RU203283U1 - Nozzles for auto-mechanical fire escapes with rotating medium expansion foam generators - Google Patents

Abstract

The utility model relates to fire extinguishing and explosion and fire prevention techniques, namely to devices for extinguishing large-scale fires of classes A and B, in particular to extinguishing fires on large tanks with flammable and combustible liquids. To increase the efficiency and safety of explosion and fire prevention and extinguishing large-scale fires with mobile fire extinguishing means of the nozzles of an auto-mechanical fire ladder contains a body made in the form of a pipeline of a fire extinguishing agent, a means for attaching the body to the steps of the stairs, located on one side of the body, a branch pipe for supplying a fire extinguishing substance to the body, a collector located on the other side of the body, and A comb in the form of a traverse, hydraulically communicating with the collector and pivotally connected to the collector with the possibility of turns in the vertical plane with four branch pipes for supplying the fire extinguishing agent from the comb to the foam generators with attached to the specified The means for attaching the body to the ladder comprises a front attachment point located on the comb side in the form of a fixed hook-shaped grip of an upstream ladder step and a rear attachment point located on the side of the fire-extinguishing supply inlet pipe in the form of a movable hook-like grip of the downstream ladder step with a lock of its position , relative to the step of the ladder mated with it. 7 p.p. f-crystals, 2 dwg., 1 tab.

Description

Technology area

The utility model relates to fire extinguishing and explosion and fire prevention techniques, namely to devices for extinguishing fires of classes A and B, in particular to extinguishing fires on large tanks with flammable liquids (FL) and flammable liquids (GF). It can be used in the oil and gas, oil refining and petrochemical industries and other sectors of the national economy for the rapid formation and uniform distribution of medium expansion foam over large areas of large-scale fires of flammable liquids, solid combustible materials and bottling of liquefied hydrocarbon and natural gases (LPG and LNG), where for to prevent repeated fires, it is required to promptly cover the entire fire-hazardous area with a fire-extinguishing agent, can be used for cooling and / or fire protection of buildings, structures, machinery, equipment, combustible and explosive materials, can be included in a set of fire-fighting tankers with foam lifters, fire ladders, car lifts, fire - rescue vehicles for foam extinguishing and other vehicles and devices for extinguishing fires of flammable liquids in tanks and on railway transport.

State of the art

Mobile and portable fire extinguishing means are known.

Known motor pump for extinguishing a fire, containing a pump with a drive motor, an engine control unit and a hose line, the pressure hose of which has a barrel-sprayer and a connector for connecting the hose to the pump, characterized in that a switch is installed on the barrel-sprayer connected by a connecting line to the unit engine control, while the pump is equipped with a heating unit for the pumped liquid, connected to the connecting line [RU 30274 A62C 25/00 Publ. June 27, 2003].

The disadvantage of this device is the low efficiency of fire extinguishing, associated with a limited amount of stored fire extinguishing agent and limited consumption of fire extinguishing agent.

Known mobile multipurpose foam generating installation for generating foam, mainly at nuclear fuel cycle facilities, including a container for water or a foam solution, a pump with an electric motor, a comb for connecting air foam generators (foam generators) of medium expansion and fire nozzles, pipelines, hoses and reinforcement, additionally equipped with foam generators of low expansion (K <20) and high expansion foam (K = 200-1000), working with two types of nets (conventional - flat or metal fabric - volumetric weaving), and a valve is installed on the comb, which allows smoothly adjusting the flow rate of the foaming solution supplied to the high-expansion foam generator with a flow rate of 0.5-10 l / min. In addition, the container is equipped with a lid designed to seal it when a pressure of up to 6 atm is created in it. These features provide an increase in the versatility of the installation [RU 2308996 A62C 27/00, A62C 5/02 Publ. 27.10.2007].

The disadvantage of this device is its significant weight and dimensions, as well as the impossibility of its use in industrial and low-rise buildings of urban and rural settlements, forest and landscape fires.

Known previously developed by the applicant, a mobile fire module containing fire extinguishing means installed on a car trailer, characterized in that, as fire extinguishing means, the mobile fire module contains at least one motor pump, at least one a container for a foaming agent, at least one container for water, fire hoses, a stationary fire installation and at least one knapsack fire extinguishing device [RU 121167 A62C 25/00 Publ. 20.10.2012].

The disadvantage of the mobile firefighting module according to RU 121167 is the possibility of using it only in places accessible for automobile movement and the impossibility of manually transferring it to and from places of fire in places that are difficult to reach for equipment.

It is known to use medium expansion foam, which has an increased fire extinguishing efficiency in extinguishing oil and oil products in comparison with low expansion foams, and medium expansion foam generators in portable and stationary versions. However, most of the known medium expansion foam generators provide foam jets from 3 to 8 m, which complicates the process of their use due to the high risk of fire brigade personnel working in the fire zone.

Known previously developed by the applicant for the formation of a jet of foam of medium expansion of increased range, in which to increase productivity, efficiency and increase the efficiency of fire extinguishing by creating a combined jet of foam of medium and low expansion and increasing the range of the jet of foam of medium expansion to 20-50 m, a solution is supplied foam concentrate on the mesh in the foam generator body to obtain a foam jet of medium expansion with the formation of a foam jet with increasing expansion and decreasing density in the direction from the center to the periphery. At the same time, two or more jets of a foaming agent solution from two or more nozzles or other means of forming directed jets are simultaneously fed to the foam generator grid with the provision of the possibility of forming in the foam generator body and / or outside of it two or more contacting and / or mutually intersecting medium expansion foam jets with the formation of a single stream of medium expansion foam with increased range [RU 2170123 A62C 5/02 Publ. 10.07.2001].

In accordance with the established requirements, above-ground storage tanks for oil and oil products with a volume of 5,000 m ³ and more must be equipped with automatic fire extinguishing means. In warehouses of the third category, in the presence of no more than two above-ground tanks with a volume of 5.000 m ^{3, it is} allowed to extinguish these tanks with mobile fire-fighting equipment, provided that the tanks are equipped with stationary foam generators of medium expansion (foam chambers, foam nozzles) and special pipelines brought out of the embankment [Guidelines for extinguishing oil and petroleum products in tanks and tank farms. - M. GUGPS, 1999].

In currently operated tanks for storing oil products without the use of a floating roof or pontoons on the surface of the liquid, intensive evaporation of oil products occurs, which leads to the formation of an explosive and fire-hazardous mixture of vapors with air in the gas space of the tank. Even with the use of modern means of lightning protection, it is not possible to avoid lightning strikes into the tank. When lightning strikes tanks filled with oil products, explosions and fires occur, which not only bring significant losses, but also lead to injuries and deaths.

Also, a fire can occur inside the embankment, which can lead to the following types of emergencies:

- heating of oil and oil product with the subsequent explosion of fuel in the tank;

- heating oil and oil products with subsequent combustion of fuel in the tank and release of oil onto the roof of the tank and into the embankment;

- volumetric explosion of a vapor-air cloud released from the reservoir in the atmosphere;

- drift downwind of a vapor-air cloud from a reservoir in the atmosphere with a possible subsequent explosion.

Oil contains a certain amount of water. According to statistical data, 80% of fires with oil were accompanied by its boiling, and 25% of such fires were accompanied by emissions [Terebnev V.V., Podgrushny A.V. Fire tactics. The basics of extinguishing fires. Yekaterinburg: Kalan Publishing House, 2010 - 512 p.].

When boiling, the temperature in the tank rises sharply. Emissions of oil from a burning reservoir occur at the moment when all the fuel is warmed up, and its temperature at the oil-water phase section reaches 200 ° C. In this case, the duration of oil emissions from the reservoir can be from 3 seconds to 7 minutes [Terebnev V.V., Podgrushny A.V. Fire tactics. The basics of fire fighting. Yekaterinburg: Kalan Publishing House, 2010 - 512 p.].

Explosions in tanks and oil spills often lead to the destruction of the roof and top walls of the tank, which consequently leads to the destruction of the fire extinguishing equipment attached to the walls at the top of the tank.

In a number of cases, an explosion in the tank caused the separation of the tank walls from the bottom along the lower weld seam with a rupture of the horizontal pipeline piping to the tank of foam fire extinguishing and water cooling systems.

Currently, the most widespread means of extinguishing tank farms of combustible and flammable liquids is air-mechanical foam, which is obtained on meshes in foam generators by ejecting air into a stream of a foaming agent solution.

When extinguishing fires with air-mechanical foam, a large amount of water and foam is consumed. In particular, when extinguishing tanks with burning gasoline, it is necessary to supply 114 liters of a 6% foaming agent solution per 1 m ^{2 of} the fuel surface [Modern fire trucks: problems of creation, innovative solutions, development trends, Kopylov N.P. // Means of rescue. Fire protection. - 2005. Catalog. - M .: 2005. - p. 66-68].

This is due to the need to create a layer of foam over the entire burning surface, which isolates the fuel from the air. When the container is partially filled, the foam falls from a great height, passing through flames and hot gases, while its destruction occurs and the extinguishing efficiency decreases. In addition, very often (about 50% of cases), at the initial moment of a fire, due to an explosion, foam generators are damaged even before the foaming agent is supplied.

Fighting tank fires with foam using built-in fire fighting equipment is usually done in two main ways:

- supplying medium expansion foam from the top of the tank to the layer of burning oil product (oil);

- supply of low expansion foam under a layer of oil and oil products.

Known installations for extinguishing fires with medium expansion foam on top of the tank on the oil product layer in most cases often do not provide fire extinguishing at the initial stage due to damage to the foam injection units from the primary explosion.

It is also known that fires in tanks with light oil products usually start with the explosion of a vapor-air mixture in the gas space of the tank and the roof tearing off or with the combustion of a vapor-air mixture in the gas space of the tank without tearing off the roof, but with violation of its integrity in some of the weakest places.

The force of the explosion affects the nature of the subsequent development of the fire. Depending on this, various destruction of the reservoir structures are observed.

Light oil products burn (gasoline, naphtha, kerosene, benzene, etc.) on a free surface more intensely than dark oil products, and the flame height reaches 20-40 m, and when pre-refined oil and dark products of its processing boil, the flame height reaches 70-80 m. Burning oil (when ejected) can soar up to a height of 80 m and be sprayed in the wind at a distance of 150 m.

Fires in tanks with oil products are extinguished, as a rule, with foam supplied to the combustion center by stationary foam chambers or mobile foam lifters [EN Ivanov. Fire protection of open technological installations. Edition 2 revised and enlarged. M., Chemistry, 1986, S. 195-196].

However, with an abnormal development of a fire, complete extinguishing by foam of ignited flammable liquids in tank farms occurs only after a few hours, and sometimes even a day, since the fire extinguishing ability of the foam is lost when it is fed into the zone of high temperatures formed near the foam drainage chamber [A.N.Baratov, E. N. Ivanov. Fire extinguishing at the enterprises of the chemical and oil refining industries. Revised 2nd edition. M., Chemistry, 1979, p. 262].

Therefore, the official recommendations [Extinguishing fires of oil and oil products in tanks: Recommendations. - M .: VNIIPO, 1991] it is proposed to stop the foam supply if the combustion is not eliminated within 30 minutes. As an example, we can point to a fire on a ground steel tank RVS with a fixed roof and a pontoon at the Moscow Oil Refinery, which could not be extinguished within 24 hours with a concentration of over 100 fire trucks [A.N.Baratov. Combustion - Fire - Explosion - Safety. M., FGU VNIIPO EMERCOM of Russia, 2003, p.332].

The experience of extinguishing fires of oil products in metal tanks shows that stationary foam discharge chambers often fail as a result of an explosion or deformation of the upper belt of the tank even before the start of extinguishing and do not give the required effect during work [EN Ivanov. Fire protection of open technological installations. Edition 2 revised and enlarged. M., Chemistry, 1986, p.202].

It is known that in the combustion zone of oil products the temperature develops up to 1100-1200 ° C, and the amount of energy released during the combustion of oil products is such that the walls above the liquid level lose strength and begin to deform [EN Ivanov. Fire protection of open technological installations. Edition 2 revised and enlarged. M., Chemistry, 1986, p.196], which accordingly leads to damage and destruction of the equipment fixed to the walls.

It is known [A.N. Baratov, E.N. Ivanov. Fire extinguishing at the enterprises of the chemical and oil refining industries. Revised 2nd edition. M., Chemistry, 1979, p. 72], that in the case of spreading over a burning product, the movement of foam slows down with distance from the place of discharge and can at some point become equal to zero. This effect is due to the fact that the destruction of the foam with increasing temperature is accelerated and a moment may come when the rates of foam inflow and its destruction become equal. Thus, the minimum foam consumption should ensure that the speed of foam movement exceeds the speed of its destruction at the points farthest from the drain points.

It is also known that when extinguishing fires in tanks with viscous and easily solidifying products (fuel oil, oils and oil), it is possible to use sprayed water to cool the surface layer of a burning liquid to a temperature below their flash point. A prerequisite for extinguishing with sprayed water is a low volumetric average temperature of the fuel (below the flash point). The intensity of the sprayed water supply should be taken as 0.2 l⋅m ² ⋅s-1 [Guidelines for extinguishing oil and oil products in tanks and tank farms. - GUGPS - VNIIPO - MIPB, 1999, p. 18. Section. The use of other substances and methods of fire extinguishing, p. 2.3.1.].

If the area of the combustible liquid is large enough and the ignition of the vapor-air mixture did not occur over its entire free surface, then the flame quickly spreads over the liquid mirror at a speed of 5-6 cm / s at the lower and upper concentration limits and 45-50 cm / s for vapor-air mixtures. the composition of which is close to stoichiometric.

Due to the fact that the flame quickly spreads over the mirror of flammable and flammable liquids, the possibilities of the noted method of extinguishing with a spray of water are limited.

Various known methods of fire extinguishing can be classified not only by the type of extinguishing agents (compositions) used, but also by the method of their application (supply), environment, purpose, etc. Fire extinguishing is subdivided, first of all, into superficial, which consists in supplying fire extinguishing substances directly to the combustion center, and volumetric, which consists in creating an environment in the area of fire that does not support combustion [Baratov A.N. Combustion-Fire-Explosion-Safety. - M .: FGU VNIIPO EMERCOM of Russia, 2004 p. 188].

Established [A.N. Baratov, E.N. Ivanov. Fire extinguishing at the enterprises of the chemical and oil refining industries. Revised 2nd edition. M., Chemistry ,. 1979, p. 73] that the advantages of foam include the fact that, unlike a number of other fire extinguishing compositions, surface extinguishing with foam does not require simultaneous (one-time) overlap of the entire mirror (area) of combustion.

It is known that the reasons for an increase in the consumption of foam per unit area of the fire center with an increase in the intensity of its supply are the mechanical difficulties in the distribution of foam on the area of the fire center and specific difficulties in spreading foam over the fuel surface. When extinguishing a fire with a large area, the possibilities of uniform distribution of foam are rather limited, therefore, the problem arises of uniform distribution of foam over the entire surface without overspending. The second reason is related to the fact that foam has different physical properties when it is at rest and when it is moving. The insulating capacity of foam in motion is reduced. In a quiet static state, the foam creates a "compacted" layer, but the transition to a static state occurs over time. The period of this transition reaches 20 s [A.N. Baratov, E.N. Ivanov. Fire extinguishing at the enterprises of the chemical and oil refining industries. Revised 2nd edition. M., Chemistry, 1979, p. 77].

Analysis of fires that occurred at technological facilities for storage and transportation of oil and oil products shows that the efficiency of using stationary automatic fire protection systems when extinguishing fires is about 7%.

The low efficiency of fire extinguishing systems with medium expansion foam and water cooling of tanks by means of equipment built into the tank is mainly due to the destruction of foam generating devices and pipelines for supplying fire extinguishing agents for extinguishing and cooling.

In this regard, the use of mobile devices for extinguishing fires on large tanks with flammable and combustible liquids is relevant.

There are known methods and devices for extinguishing fires on large tanks with flammable and combustible liquids, but they are not effective enough.

There is a known fire extinguishing system in vertical tanks for storing oil products at temporary accommodation points for the population affected in an emergency, in which, to increase the reliability of extinguishing a fire of oil products in vertical steel tanks with any type of roof without human intervention, a foam generator is stationary mounted on a telescopic lift outside the tank and a sleeve is connected, which is connected to the supply pipeline and tanks with foaming agent and water. In the lower part, a telescopic lift mounted on a support is connected to a piston that is located in a cylinder. A limiter for the movement of the telescopic lift is installed on the foundation. There are seals and stops at the top of the links of the telescopic lift. An air supply line is connected to the cylinder with the piston and the telescopic lifter, which is connected to the cylinders filled with compressed air. Outside the RVS, below the freezing level of the soil, two horizontal tanks of the corresponding capacity are installed, one of which is filled with water, and the other with a foaming agent. The reservoirs are sealed and interconnected by an air duct. Moreover, the pipeline connecting the reservoir with the foaming agent to the supply pipeline has a dispenser. The compressed air cylinder is connected to the air line and the water tank and the foaming agent. The compressed air cylinder is equipped with a pressure regulator and a squib valve. In the upper part of the RVS, pressure and temperature sensors are installed, which are connected to the squib crane and have an autonomous power system (for example, batteries) [RU 141291 A62C3 / 06 Publ. 05/27/2014]

A device for fire extinguishing of a combustible liquid in a tank is known, used in combined automatic systems for foam fire extinguishing of oil and oil products in vertical steel tanks with a pontoon, with a floating roof or without them, as well as in reinforced concrete tanks, and can be used in the oil industry. The device contains a low expansion foam generator and a foam container. The low expansion foam generator is made in the form of a housing with a nozzle for feeding a foaming agent solution into the housing and with an opening for supplying air to the housing. The nozzle is multi-jet. In the housing of the low expansion foam generator there is a mixing chamber, the inlet of which is installed opposite the nozzle, and the outlet is connected to a foam container having an outlet for foam into the reservoir in the form of at least two slit-like openings with the possibility of supplying a flat fan-shaped jet by one of them to the combustible liquid in the tank, and the other on the inner wall of the tank. Between the outlet for foam from the foam container to the tank and the mixing chamber, there is a sealing membrane that bursts under the influence of the foam pressure. For testing the device, it contains a plug, made with the possibility of installation between the bursting disc and the low expansion foam generator, and an opening with a lid located on the foam container up to the plug. EFFECT: increased efficiency of fire extinguishing due to stable achievement of foam rate not lower than 8 [RU 2232041 A62C3 / 06 Publ. 10.07.2004].

The known system for automatic extinguishing of oil products in vertical steel tanks (RVS) with any type of roofs without the participation of a fire brigade, the resistance of fire-fighting equipment to the explosion of a vapor-air mixture. This problem is solved with the help of a movable telescopic lift with a foam generator attached to it, which is connected to tanks filled with water and a foam concentrate and connected by an air duct with compressed air cylinders. Outside the RVS, below the freezing level of the soil, two horizontal tanks of the corresponding capacity are installed, one of which is filled with water, and the other with a foaming agent. The reservoirs are sealed and interconnected by an air duct. Moreover, the pipeline connecting the reservoir with the foaming agent to the supply pipeline has a dispenser. The compressed air cylinder is connected to the air line and the water tank and the foaming agent. The compressed air cylinder is equipped with a pressure regulator and a squib valve. In the upper part of the RVS, pressure and temperature sensors are installed, which are connected to the squib crane and have an autonomous power supply system (for example, batteries) [RU 2359723 A62C31 / 12, A62C3 / 06].

A known system for extinguishing fires on large tanks with flammable and combustible liquids (options). The essence of the first version of the extinguishing system device is that it includes N≥2 controllable foam generator shafts located along the perimeter of the tank, the foam generator shafts are located at an angle of minus 2-10 degrees to the horizontal surface of the combustible liquid, at the base of the fire flame, it is used homogeneous water-air foam with a multiplicity of Kp equal to 30 ± 10, a range of supply of a foam jet L, greater than or equal to the radius R of the reservoir, an intensity I of foam supply equal to 0.1-0.15 l / m ² ⋅s, while a controlled foam jet is supplied in the horizontal plane with the angle of rotation of the barrel axis by ± 45 degrees and in the vertical plane with the angle of rotation of the axis of the barrel by ± 5-10 degrees. The second version of the system differs from the first in that the foam generators are located along the perimeter of the tank on the ground or small mobile platforms, homogeneous water-air foam is used with the same multiplicity Kp equal to 30 ± 10, the range of the foam jet L, greater than or equal to the radius R of the tank, with an intensity I supply of foam equal to 0.15-0.5 l / m ² ⋅s, while the foam stream controlled from the ground is supplied through the side of the tank. The angle of inclination of the shaft of the foam generator relative to the ground is 60-80 degrees. [RU 2651784 A62C 3/06 Publ. 04/23/2018].

It is believed that to cool the walls of the burning and adjacent tanks, it is enough to create a ring of water irrigation [E.N. Ivanov, Fire protection of open technological installations, 2nd edition revised and enlarged. M., Chemistry, 1986, p. 200], however, as shown above, water spray systems are often destroyed by explosions in the reservoir.

The known method of surface extinguishing of a fire in tanks with petroleum products [SU 1400621 A62S31 / 12, A62S1 / 12 Publ. 04.06.88] according to which, to increase the efficiency of extinguishing a fire with air-mechanical foam of increased expansion, as well as the speed of spreading over the surface of oil products, the ejection jet is fed in the direction of the side surface of the tank, along its chord along the mirror of the oil product, which makes it possible to cool the hot metal wall of the tank, being a screen for a jet of foam of increased expansion. Fire extinguishing is carried out by the simultaneous supply of adjacent jets, which contribute to the rapid spreading of foam over the surface of the oil product mirror, thereby creating favorable conditions for the final extinguishing by isolating the vapors of the combustible liquid from the combustion zone.

A device for extinguishing a fire in a tank with petroleum products is known, which contains a means for moving the foam generator, made in the form of a hinge-lever mechanism, including a hinge support and a counterweight, and installed on the side surface of the tank, and a pipeline for supplying extinguishing agent to the foam generator with fixation means. In this case, the pipeline for supplying the extinguishing agent is made in the form of an elbow of two hinged sections, the upper of which is located at an angle to the lower section, and the upper section of the pipeline is installed on a hinged support, and the lower section of the pipeline is used as a counterweight. In the event of a fire, a flexible hose is connected to the lower section of the supply pipeline through the connecting piece for supplying the foaming agent solution. The supply pipeline filled with a solution under the influence of gravity takes a strictly vertical position, turning the elbow. In this case, the foam generator makes a complex movement up and forward, introducing the foam generator into the fire zone. At the end of extinguishing, the supply pipeline is freed from the foaming agent solution and it returns to its original position manually or using a return mechanism mounted on the bracket [SU 1606132A62C31 / 00 Publ. 15.11.90 Bul. No. 42].

A common disadvantage of the known methods and devices for extinguishing fires in tanks with petroleum products is the unsatisfactory efficiency of the process of extinguishing fires in large tanks with flammable liquids and combustible liquids, the structural complexity of devices located inside the tanks or attached to the upper parts of the walls of tanks, which become inoperative during explosions and destructions. upper parts of tanks in case of fires.

There is a known method of extinguishing fires on large tanks with flammable and combustible liquids by feeding from foam-generating barrels N≥2, located along the perimeter of the tank from above, on the inner surfaces of the tank of jets of fire extinguishing agent, foam is supplied by jets to the surface of the combustible liquid of the tank by scanning in the vertical and horizontal planes programmatically -controlled or oscillating foam-generating shafts in the sector allocated for each shaft based on the foam coverage of the entire surface of the combustible liquid. In this case, the foam is supplied according to the fire extinguishing control program to the wall and from the wall of the tank synchronously from all foam-generating shafts, gradually shifting towards the center of the tank and tangentially to the fire to the area pre-cooled with foam; the fire extinguishing control program is corrected by coordinate infrared sensors installed on the foam-generating trunks or a quadruple, according to the data on the coordinates of the areas of combustion sources; foam with water mist is used as a fire extinguishing agent; for the supply of foam, foam-generating trunks are used, forming foam with water mist [RU 2684743 A62C 3/06 Publ. 04/12/2019]

The disadvantages of the method according to RU 2684743 are the complexity of the design and the impossibility of practical effective use, namely:

- the complexity of the equipment in the form of software-controlled oscillating foam-generating shafts with scanning (i.e. reading the state of the fire surface) in the vertical and horizontal planes;

- the complexity of the claimed synchronized operation of all foam-generating barrels, since the synchronization of work is associated with a radiation source that does not have clear boundaries of the surface and volume of the flame and compatibility with barrels equipped with coordinate infrared sensors, especially those placed on a quad, the operation of which depends on smoke, weather conditions , wind speed and direction, etc .;

- the inadmissibility of the declared supply of foams simultaneously with finely sprayed water, since this violates the principle of the existence of the air-mechanical foam itself, since it is well known that sprayed water intensively destroys the foam;

- inexpediency of supplying foam with a spray angle of more than 30 ° ^, since this sharply reduces the range of foam jets as a result of increasing the drag of the jet and intensifying the destruction of foam under the influence of thermal and convective flows of the flame;

- the impossibility of synchronizing the work of the tables placed behind the embankment due to erroneous operation of the infrared sensors of the barrels aimed at the combustion center in the reservoir.

In conditions of a high rate of propagation of combustion on tanks with flammable and combustible liquids, the use of mobile mobile means of supplying extinguishing agents is required, which can limit the spread of combustion, provide fast and effective extinguishing of a fire.

Known fire fighting foam, containing placed on the vehicle, a rotary platform with a telescopic boom and a support stand. On the upper section of the boom there is a water-foam pipe with several parallel-mounted nozzles. The boom has the ability to turn and lift to the required angle. The water pipe is made sliding and, moreover, is installed on a carriage that can move along the boom, and, therefore, can move over the mirror of the tank, which increases the fire extinguishing area. The device is used to extinguish fires at oil loading facilities (USSR author's certificate No. 1627193, A62S 27/00, 15.02.91).

The disadvantage of the SU 1627193 device primarily lies in the fact that the nozzles form a directed compact stream of extinguishing agent, which does not allow providing the required rate of supply of extinguishing liquid to the maximum area of the fire at the same time, which reduces the efficiency of flame extinguishing. In addition, the specificity of the nozzles does not allow the use of water as a fire extinguishing liquid in the known device, which narrows its functionality.

Known fire and rescue complex for extinguishing fires and rescuing people on fires. The complex contains a tank with a fire-extinguishing (fire-extinguishing) substance and a lifting device located on the vehicle. A pipe with a distribution device for supplying extinguishing fluid through flexible hoses to three fire nozzles fixed on controlled movable platforms located on a common bracket is installed on the lifting device (RU 2191612, А62С 27/00, 27.10.2002).

The disadvantage of the RU 2191612 device is that an increase in the area of extinguishing a fire covered by this device when extinguishing it is provided due to the possibility of individual reversal of fire nozzles and work in one or different places of the fire object. At the same time, fire nozzles form a directed compact stream of extinguishing agent, which does not allow simultaneously providing the required intensity of supply of extinguishing liquid to the maximum area of the fire, which reduces the efficiency of flame extinguishing.

Known fire ladder, which is a fire truck equipped with a stationary mechanized retractable and rotary ladder, designed, in particular, to supply fire extinguishing substances to a height. At the top of the first knee of the ladder, there is a removable fire monitor with manual (cable) or remote (based on electric drives) control (http://vunivere.ru/work56495/page4 "Memo to the driver-operator of the fire ladder AL-30 (131) PM- 506D ", part 2, page 4, Fig. 3.4).

The disadvantage of this device is that the fire barrel forms a directed compact stream of extinguishing agent, which does not allow providing the required intensity of the extinguishing liquid from above to the maximum area of the fire and reduces the efficiency of flame extinguishing, increases the time of extinguishing the fire, and reduces the safety of the personnel. In addition, the device allows the use of only one fire barrel, which reduces the area of the irrigated surface, reduces efficiency and increases the time to extinguish the fire. At the same time, a fire monitor installed on the stairs requires manual control, for example, by means of ropes, or remote control, for example, based on electric drives, which in northern conditions at low winter temperatures reduces the operational reliability of the device.

Known mobile multipurpose foam generating installation, including a container for water or a foam concentrate, a pump with an electric motor, a comb for connecting medium expansion foam generators and fire nozzles, pipelines, hoses and fittings, is additionally equipped with low expansion foam generators (K <20) and high expansion foam (K = 200-1000), a valve is installed on the comb that allows you to regulate the flow rate of the foaming solution supplied to the high expansion foam generator with a flow rate of 0.5-10 l / min. The container is equipped with a lid designed to seal it when creating a pressure of up to 6 atmospheres in it using third-party sources of compressed air, such as a compressor or a cylinder with compressed air or inert gas (nitrogen, carbon dioxide) of high pressure, equipped with a reducer. The installation is mounted on a trolley [RU 2308996, A62C 27/00, publ. 2007)].

The disadvantage of the analogue is that the design does not have the ability to adapt to the method of extinguishing oil tanks using a foam lifter, which is most often used in the practice of extinguishing fires, and excludes mobile remote movement and control of fire nozzles (changing the height and angle of the fire nozzle feed, foam rate) from the control pump section of the foam lifter at the height of extinguishing tanks and installations of oil products. The design of the installation provides for a pump that excludes the possibility of using a fire engine pump and reduces the mobility of use with the existing equipment of the fire department. The installation has a container for a foam concentrate or water in its design, which reduces its mobility when extinguishing a fire, despite the presence of a cart, since the speed of movement and combat deployment of a fire engine with a cart is much lower. The design includes a compressor, a compressed air cylinder and a reducer, complicating the operation of the unit and reducing the mobility of use. The design provides for the need to stretch at the height of several working hose lines with fire hoses for each type of fire nozzle separately, which reduces the speed of movement of the complex of fire nozzles, reduces the time of combat deployment in case of a fire due to an increase in weight and additional fire-fighting equipment.

Known fire and rescue complex for extinguishing fires and rescuing people on fires and allows you to increase the efficiency of extinguishing fires simultaneously in several places of the object and to save people with an extreme lack of time in extreme situations. The complex contains a tank with a fire extinguishing agent and a lifting device located on the car. A pipe with a distribution device for supplying extinguishing liquid to three fire nozzles is mounted on the lifting device, fixed on controlled movable platforms located on a common bracket. A console with a video camera and a spotlight is attached to the bracket. The car has a trailer equipped with life mats, ladder and belt ties. The car is equipped with a compressor for emergency pumping of mats [RU 2191612 A62C 27/00, publ. 27.10.2002 Bul. No. 30].

Known universal fire installation combined method of extinguishing the fire of tanks of oil products and installations of the oil and gas industry, including a connecting head, a foam generator with a grid for breaking fire foam, a switch for changing the multiplicity of foam. On the path of the solution passage, a two-way branching is installed through the connecting heads, which is a steel pipe branched into two, in the place of the branching of the pipes on the inside there is a shut-off valve, to which a remote switch transmits a mechanical force by applying an electrical signal to an electric drive located in the control compartment of the foam lifter, through a corrugated tube with an electric cable, laid through the entire length of the knees of the foam lifter, to change the path of movement of the foam solution and the expansion rate of the foam, then the foam solution enters a typical fire barrel. When using the combined method of extinguishing a fire of oil and oil products, it is proposed to stage-by-stage supply of low and medium expansion foam to the combustion center using a universal fire unit with a high foam consumption and with the possibility of remotely changing the expansion rate produced in the foam barrel. [RU 2631170 A62C 27/00, publ. 19.09.2017 Bul. No. 26]

... Known actuators are devices that transfer force from a control or regulating mechanism to an actuator and allow circular or linear movements. In most cases, such devices are used to obtain mechanical energy from electrical energy. There are linear actuators that convert mechanical energy into linear movement, and rotation actuators that provide rotary movement [https://electrosam.ru/glavnaja/jelektrooborudovanie/ustrojstva/aktuatory/, 20.07.2018].

A device for combined extinguishing of large-scale fires of classes A and B and for fire and explosion prevention with air-mechanical combined foam of low and medium expansion is known. To increase the efficiency of fire extinguishing and explosion and fire prevention by increasing the range and uniformity of distribution of medium and low expansion foam over the fire area and increasing the safety of the process of extinguishing fires and fire and explosion prevention at especially fire and explosion hazardous facilities, a device for combined fire extinguishing and fire and explosion prevention with low and medium expansion foam contains two a traverse of a combined foam generator of low and medium expansion, containing a housing with a package of grids for generating foam of medium expansion located inside the housing, a block of nozzles for supplying an aqueous solution of a foaming agent to a package of grids for generating foam with a medium expansion, a shaft for forming a foam of low expansion, a pipeline for supplying an aqueous solution of a foaming agent to the nozzles and the low expansion foam formation shaft and the means for connecting the foam generator to the pressure pipeline. The means of automated turns of the traverse with foam generators fixed on it in the vertical and horizontal planes are made with the possibility of connecting them to the remote control system and with the possibility of remote control by means of a remote control or radio signals of the remote control system. The means for automated turns of the crosshead with foam generators fixed on it in the vertical plane is made in the form of an actuator containing a linear drive and an electric motor, and the means for automated turns of the crosshead with foam generators fixed on it in the horizontal plane contains a gear rotation and an electric motor. [RU 2703592 A62C15 / 00, publ. 21.10.2019 Bul. No. 30]

The closest in technical essence and the achieved technical result (prototype) is a device for supplying liquid fire extinguishing substances to a height, containing rigidly fixed on the top of the upper section of the ladder boom, a comb-type distributor connected to the upper end of the hose line. The nozzles of the comb are connected to the fire nozzles by means of the connecting heads of the firemen fixed to them. The barrels are equipped with central and peripheral nozzles. The axes of the nozzles are located at an angle to the axis of the barrel body. The barrels are facing down with the nozzles. This provides an increase in the efficiency of fire extinguishing due to the possibility of providing the required intensity of supply of the extinguishing liquid from above to the maximum area of the fire and due to the precise supply of the extinguishing liquid; reducing the time for extinguishing an open developed fire, increasing the safety of personnel by supplying a fire extinguishing liquid without involving personnel to work at height under the influence of dangerous fire factors, increasing the operational reliability of the device in conditions of low winter temperatures in the north; expanding the tactical and technical capabilities of the operational departments of subdivisions. [RU 2657687 A62C 31/00, publ. 06/14/2018 Bul. No. 17 (prototype)]

The essence of RU 2657687 (prototype) is that in a device for supplying liquid fire extinguishing substances to a height, containing a fire ladder, along the steps of the boom of which a hose line is laid along the axis, the lower end of which is connected to the fire pump of the main fire engine, and a fire barrel, fixed to the top of the top section of the ladder boom. Distinctive is that at the top of the upper section of the ladder boom is rigidly fixed to the upper end of the hose line a comb-type distributor with nozzles for supplying a liquid fire extinguishing agent, equipped with connecting fire heads, in addition, additional fire nozzles are introduced, and the total maximum number trunks corresponds to the number of nozzles. Each barrel contains a body in the form of a hollow pipe, one end of which is equipped with a coupling fire head, by means of which the barrel is connected to the connecting head of the corresponding branch pipe of the switchgear. A cover is welded to the second end of the barrel body, in which an axial hole and peripheral holes are made, located radially at an equal distance from the axis of the body and at an equal distance from each other. A hollow cylindrical adapter is installed on each hole and welded to the outer surface of the cover, while the peripheral adapters are welded in such a way that their axes are located at the same acute angle to the body axis, which is 20 ° -30 °. The inner diameter of the adapter is not less than the diameter of the hole, and a thread is made on the inner surface of the adapter along the entire length. A cylindrical nozzle is screwed into each adapter coaxially with a threaded seating end, in which a through cylindrical axial hole with a sharp leading edge is made, while the total length of the nozzle satisfies the condition: l = (3 ... 4) d, where l is the total length of the nozzle , d is the diameter of the through axial hole. The length of the landing end of the nozzle is at least half of its total length. The thread at the seating end of the nozzle is limited by a nut welded to the outer surface of the nozzle. The total length of the central nozzle is 39-45 mm with a through hole diameter of 13-15 mm, and the total length of the peripheral nozzle is 36-40 mm with a through hole diameter of 9-10 mm.

The disadvantage of the device RU 2657687 (prototype) is its intended use for extinguishing an open developed fire of one- and two-storey residential, public and office buildings of IV-V degrees of fire resistance by suppressing jets of water from top to bottom and unsuitable for extinguishing fires on large tanks, where rapid coverage with medium foam is required. multiplicity of large areas of ignition.

A common disadvantage of known similar fire extinguishing devices is the insufficient efficiency of fire extinguishing, the possibility of the formation and supply of separate jets of foam or sprayed water to the fire zone in certain, point fire places, which is effective only when extinguishing small fires in low-rise residential and industrial buildings in urban and rural settlements , when extinguishing forest, road and other landscape fires This does not allow to provide a controlled quick and uniform coverage of the entire fire area with foam, which, in turn, causes a significant decrease in the efficiency and speed of extinguishing large fires.

No identical attachments were found in the scope of the search.

Task and technical result

The objective of the claimed utility model is to improve the efficiency and safety of explosion and fire prevention and extinguishing large-scale fires with mobile fire extinguishing means.

The technical problem to be solved by the claimed utility model consists in the need for prompt formation and uniform distribution of medium expansion foam over large areas of fire of combustible liquids, solid combustible materials and bottling of liquefied hydrocarbon and natural gases (LPG and LNG), where, in order to prevent repeated fires, requires operational coverage with a fire extinguishing agent of the entire fire hazardous area, cooling and / or fire protection of buildings, structures, machinery, equipment, combustible and explosive materials.

The technical result achieved by the implementation of the claimed invention is to increase the efficiency and safety of explosion and fire prevention and extinguishing of large-scale fires with mobile fire extinguishing means through the use of the proposed nozzle with foam generators for an auto-mechanical fire ladder in a set of equipment for fire tankers with a foam hoist, fire ladders, car lifts, fire and rescue vehicles and other mobile equipment.

The essence of the utility model

The problem is solved and the required technical result when using the utility model is achieved by the fact that the nozzle of an auto-mechanical fire escape ladder with rotating foam generators of medium expansion according to the utility model contains

a body made in the form of a pipeline of a fire-extinguishing agent,

attached to the body from below, a means of attaching the body to the steps of the stairs,

a branch pipe located on one side of the body for supplying a fire extinguishing agent to the body,

the manifold located on the other side of the housing and

a comb in the form of a traverse, hydraulically connected to the manifold and pivotally connected to the manifold with the possibility of turns in the vertical plane

with four nozzles for supplying a fire extinguishing agent from a comb to foam generators with four foam generators connected to said nozzles with the possibility of generating contacting jets of medium expansion foam or sprayed water when an aqueous solution of a foaming agent or water is fed into them, respectively.

The means for attaching the nozzle body to the ladder contains a front attachment point located on the comb side in the form of a fixed hook-shaped grip of an upstream ladder step and a rear attachment point located on the side of the fire extinguishing supply pipe in the body in the form of a movable hook-like grip of a downstream ladder step with a lock of its position relative to the ladder mated with it stair steps.

The body of the nozzle can be provided with handles located on the sides of the body, preferably in the region of the center of gravity of the nozzle, for carrying and installing the nozzle on the rungs of the stairs.

The means for connecting the foam generators to the fire-extinguishing agent supply pipes to the foam generators located on the comb are made in the form of quick-detachable connections, and the fire-extinguishing agent supply pipe to the body is equipped with a quick-detachable connection means with the fire-extinguishing substance pressure pipeline, made, for example, in the form of a fire hose.

The articulated connection of the manifold and the comb with the foam generators is equipped with fixers for the angles of rotation of the comb with the foam generators relative to the collector and may contain means for remote control of the comb with the foam generators relative to the collector by means of electrical or radio signals and can be made in the form of an actuator.

Brief Description of Drawings

The essence of the utility model is illustrated by drawings of the design of the proposed nozzle with foam generators for an auto-mechanical fire escape with rotating foam generators of medium expansion, where shown in the positions: 1 - body; 2 - foam generators; 3 - block of nozzles; 5 - front attachment point; 6 - rear attachment point with a latch; 7 - connecting head of the fire extinguishing agent supply pipe; 8 - retractable auto-mechanical ladder, 11 - collector, 12 - means for fixing the angle of rotation of the comb with foam generators relative to the collector.

FIG. 1-2 shows general views of the proposed nozzle for an auto-mechanical fire escape with rotating medium expansion foam generators.

Implementation of the invention

The proposed nozzle for an auto-mechanical staircase with rotating foam generators may contain medium expansion foam generators UKTP "Purga-5" produced by the applicant (LLC NPO Modern Fire Technologies), forming combined contacting jets of medium expansion foam, and is designed to supply air to the fire extinguishing site. -mechanical foam of medium expansion or sprayed jets of water.

A feature of the proposed nozzle is the joint horizontal arrangement of foam generators, which makes it possible to create a wide flat front of the jet of air-mechanical foam of medium expansion or sprayed water with the possibility of adjusting the angle of inclination to the plane of the fire, which, in turn, provides the possibility of a quick and adjustable coating with a fire extinguishing agent the entire surface of the fire or the protected surface by using a mobile auto-mechanical ladder, which significantly increases the efficiency of extinguishing large-scale class A and B fires with foam or sprayed water.

This device - nozzles with medium expansion foam generators can be included in a set of fire-fighting tankers with a foam lifter, fire ladders, car lifts, fire-fighting and rescue vehicles with water-foam extinguishing and other vehicles and devices for extinguishing fires of flammable liquids in tanks and on railway transport.

Foam generators 1 in the nozzle are located on a horizontally located comb in the form of a traverse in one row with the possibility of obtaining contacting jets of low and medium expansion foam or sprayed water when an aqueous solution of a foaming agent or water is supplied to them, respectively, and the formation in the fire zone and explosion and fire prevention of a single a combined flat jet of extinguishing agent with an adjustable angle of inclination to the surface of the fire or fire prevention.

An aqueous solution of a foaming agent or water is first fed into the nozzle body, then through the comb into the nozzles 4 of the foam generators and directed to the mesh pack. Due to the ejection of air by a stream of solution, medium expansion foam or sprayed water is formed on the grids.

It is connected to the pressure pipeline of a car lift with a ladder of nozzles using a quick-disconnect connection 7 on the branch pipe for supplying a fire-extinguishing agent to the nozzle body.

The work of the nozzle begins with the supply of water or an aqueous solution of a foaming agent to the pressure pipeline under a pressure of at least 0.8 MPa (8 kgf / cm ² ).

As a result, contacting streams of sprayed water or foam of medium expansion at the outlet of the foam generators form one common wide and flat combined stream of extinguishing agent.

Falling on a burning or protected surface, a stream of foamed or sprayed extinguishing agent cools and isolates the combustion zone from the ingress of combustible vapors and gases, as well as atmospheric oxygen, and eliminates or prevents combustion.

Technical characteristics (parameters) of a nozzle with 4 foam generators with a productivity of 5 l / s are shown in table 1.

Table 1.

Main operating parameters of the nozzle with 4 foam generators

P / p No. Parameter name Unit measurements. Value one. Operating pressure MPa 0.8 2. Total water consumption at operating pressure l / s twenty 3. Consumption of an aqueous solution of a foaming agent at operating pressure l / s 20 + 4 four. Foaming agent consumption at operating pressure l / s 1.6 ± 0.2 five. Range of jets (by extreme drops) at operating pressure:
- water
- foam m 20 ± 2
20 ± 2 6. Foam ratio 50 ... 70 7. Overall dimensions of the unit (LxWxH) mm 1000х1300х470 eight. Installation weight Kg 33

The principle of operation of the nozzle is as follows: the flow of a solution of a foaming agent or water under a pressure of 0.8 MPa is fed through the body to the block of nozzles of the foam generators and is directed to the formation of medium expansion foam jets or sprayed water jets on the foam generators grids.

Falling on a burning surface, foam or sprayed water isolates the combustion zone from the ingress of combustible vapors and gases, as well as air oxygen, and eliminates combustion or cools the combustion zone, prevents ignition.

If necessary, the attachments can be used to cool a burning object, or an object located next to a burning one, or to extinguish solid combustible materials, as well as to deposit toxic chemical vapors.

Installation of a nozzle on an auto-mechanical ladder is carried out mainly at the place of its use in the following sequence:

- the front attachment point 5 is brought into engagement with the upper step of the ladder;

- the rear assembly is brought into engagement 6 with the lower stage and its position is fixed with a locking screw;

- by means of a quick-detachable connection 7, the connecting head of the fire-extinguishing agent supply pipe is connected to the pressure pipe of the extinguishing agent, made, for example, in the form of a fire hose

When extinguishing fires, they are guided by the Combat Regulations of Fire Protection Units, which determine the procedure for organizing fire extinguishing and carrying out emergency rescue operations (Order No. 444 of the Ministry of Emergency Situations dated October 16, 2017)

The position of the nozzle on the car lifter is oriented in relation to the burning object so that, if possible, the angle of supply of the jets of the extinguishing agent to the burning surface is as small as possible, the working pressure is set and its value and consumption of the extinguishing agent are controlled.

The pressure in the nozzle body must be increased gradually, bringing it up to the worker. After stabilization of the water jet (reaching the operating parameters), the foaming agent is fed into the pressure line and the installation.

The supply (consumption) of the foaming agent is also increased gradually, bringing the concentration of the foaming agent in the solution to the working value (4% - 6%).

It is not allowed to supply foam (or water) to open power lines, railway overhead wires and other live electrical equipment.

As foam generators can be used, in particular, combined fire extinguishing units UKTP "Purga" produced by the applicant - NPO Modern Fire Technologies LLC.

Each foam generator in a nozzle can contain nozzles, nozzles, a body and a package of meshes, which together provide foam jets, mainly of low and medium expansion 40 + 35.

When an aqueous solution of a foaming agent is fed into the generator as a fire extinguishing agent into the device under operating pressure, jets of air-mechanical foam are formed and fed to the protected area.

For a more even distribution of the fire extinguishing agent (over the area of the protected surface, part of the foam generators can be located horizontally on the comb, and part can be located obliquely to the horizontal plane.

The nozzle can be used and operated without the participation of personnel, that is, as an automated foam or spray water generator.

When the pressure of water or an aqueous solution of a foaming agent is more than 0.2 - 0.3 MPa in the nozzle body, the formation of jets of sprayed water or air-mechanical foam begins in the foam generators.

The working parameters of the nozzles comes out when the pressure reaches 0.6-0.8 MPa.

The authors' studies and full-scale fire tests of the design options of the nozzle shown in the drawings showed a confident solution to the task and the achievement of a technical result, namely, effective localization and extinguishing of a fire in areas of 200 square meters or more, which corresponds to the cross-sectional areas of large oil and oil products reservoirs.

It has also been experimentally established that it is advisable to predominantly use combined fire extinguishing units UKTP "Purga-5" manufactured by NPO Modern Fire Technologies LLC as foam generators, which provide the supply of combined low and medium expansion foams and sprayed water at distances of up to 30 m.

Thus, all the essential features of the utility model are in a causal relationship with the technical result obtained from the use of the invention.

The specific design features of the device were determined experimentally and practically verified in the course of field tests, which is confirmed by the attached drawings.

Full-scale tests of the device have shown a confident solution to the task and achieve the required technical result - increasing the efficiency and safety of fire extinguishing.

The device can be effectively used to extinguish large-scale fires of classes A and B with foam. It can be included in a set of fire-fighting tankers with a foam lifter, fire ladders, car lifts, fire-fighting foam extinguishing vehicles and other vehicles and devices for extinguishing fires of flammable liquids in tanks and on the railway. transport.

The structural and technological features of the utility model, disclosed in detail above and shown in the drawings, prove not only the causal relationship of the essential features and the technical result, but also prove the possibility of industrial implementation of the utility model, confident achievement of the technical result, namely, with the industrial implementation of the utility model, an increase in efficiency and fire extinguishing safety.

As individual elements and units of the device, various known and traditional fire-fighting technologies, materials and design solutions can be used, which are usually used in the elimination of accidents, prevention of fire and explosion (stopping) and extinguishing fires of flammable and combustible liquids in relation to specific conditions.

Considering the novelty of the set of essential features, the technical solution to the problem posed, the materiality of all general and particular features of the utility model, proven in the "State of the art" section and "Disclosure of the utility model, proven in the section" Implementation of the utility model ", the technical feasibility and industrial applicability of the utility model, successful the solution of the inventive problem posed and the confident achievement of the required technical result during the implementation and use of the utility model, in our opinion, the declared utility model meets all the protection requirements for utility models.

The analysis also shows that all general and particular features of a utility model are essential, since each of them is necessary, and all together they are not only sufficient to achieve the goal of the utility model, but also allow the utility model to be implemented in an industrial way.

Claims (14)

1. The nozzle of an auto-mechanical fire escape, characterized by the fact that it contains a body made in the form of a pipeline of a fire-extinguishing agent, attached to the body from below, a means of attaching the body to the steps of the stairs, a branch pipe located on one side of the body for supplying a fire extinguishing agent to the body, the manifold located on the other side of the housing and a comb in the form of a traverse, hydraulically connected to the manifold and pivotally connected to the manifold with the possibility of turns in the vertical plane with four nozzles for supplying the fire extinguishing agent from the comb to the medium expansion foam generators with four medium expansion foam generators connected to the said nozzles with the possibility of generating contacting jets of medium expansion foam or sprayed water when an aqueous solution of a foaming agent or water is fed into them, respectively. 2. Nozzles for an auto-mechanical fire ladder according to claim 1, characterized in that the means for attaching the body to the ladder comprises a front attachment point located on the comb side in the form of a fixed hook-like grip of an upstream ladder step and a rear attachment point located on the side of the fire extinguishing supply pipe in the form of a movable hook-shaped grip of the lower step of the ladder with a fixing of its position relative to the step of the ladder mating with it. 3. Nozzle for an auto-mechanical fire escape according to claim 1, characterized in that the body of the nozzle is provided with handles located on the sides of the body, mainly in the region of the center of gravity of the nozzle, for carrying and installing the nozzle on the steps of the stairs. 4. Nozzles for an auto-mechanical fire escape according to claim 1, characterized in that the means for connecting medium expansion foam generators to the pipes for supplying the fire extinguishing agent to the foam generators located on the comb are made in the form of quick-detachable connections. 5. Nozzles for an auto-mechanical fire escape according to claim 1, characterized in that the branch pipe for supplying the fire-extinguishing agent to the body is equipped with a means of quick-detachable connection with the pressure pipe of the fire-extinguishing agent, made, for example, in the form of a fire hose. 6. Nozzles for an auto-mechanical fire escape according to claim. 1, characterized in that the articulated connection of the collector and the comb with the foam generators of medium expansion is equipped with fixers for the angles of turns of the comb with the foam generators relative to the collector. 7. Nozzles for an auto-mechanical fire escape according to claim 1, characterized in that it contains a means for remote control of the comb turns with foam generators of medium expansion relative to the collector by means of electrical or radio signals. 8. Nozzles for an auto-mechanical fire escape according to claim 7, characterized in that the means for remote control of the angles of turns of the comb with foam generators of medium expansion relative to the collector in the form of an actuator.

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