RU2684743C1 - Method of extinguishing fires on large reservoirs with flammable and combustible liquids - Google Patents

Abstract

FIELD: fire-fighting equipment.SUBSTANCE: invention relates to fire extinguishing and concerns elimination of accidents occurring on reservoirs with capacity of 5 thousand mand more with highly flammable liquids (HFL) and combustible liquids (CL), which result is fire of combustible liquids. Method of fire extinguishing on large tanks with flammable and combustible liquids by supply from foam generating shafts N≥2, arranged along perimeter of reservoir from above, on inner surface of tank of jets of fire extinguishing substance. According to invention, foam is supplied by jets to the surface of combustible liquid of reservoir by scanning in vertical and horizontal planes by software-controlled or oscillating foam-generating shafts in the sector allocated for each shaft in terms of foam coating of entire surface of combustible liquid.EFFECT: as a result, efficiency of fire extinguishing process on large reservoirs with HFL and CL at simultaneous simplification of known technology and devices used for its implementation is increased.9 cl, 7 dwg

Description

The invention relates to the field of fire fighting and the elimination of accidents occurring on tanks with a capacity of 5 thousand m ³ and more with flammable liquids (flammable liquids) and flammable liquids (GJ), which result in a fire of flammable liquids.

Known methods for the elimination of emergency spills of liquefied natural gas or liquefied petroleum gas and a system for their implementation by treating the surface of liquefied gas with water-foam - patents RU 2552968 C1, 2015, RU 2552972 C1, 2015

Known methods are impractical for extinguishing fires on large tanks of flammable liquids and liquids because of the type of fire extinguishing agent (OS) used - a combined foam, which is a mixture of two foams of different multiplicity: Кп = 10-15 and Кп = 80-100, complicated in the technology of their separate receiving in 2 foam generators of various designs and the subsequent mixing of these foams with different kinetic energy into the total flow of the combined foam jet. Only in such a complicated way is it possible to obtain the required parameters by the foam multiplicity of order Kp = 40 and the flight distance of foam jets at a distance of 30-50 meters or more.

Closest to the proposed method is a method of extinguishing a fire in tanks, in which the foam is fed into the tank from above. A device for protecting reservoirs with flammable and combustible liquids from an explosion and in case of fire is known, which contains an input of a fire extinguishing substance with an outlet to the reservoir at one end and with a lid on the other, and a foam generator with a nozzle — a foam generating foam supplying foam additionally containing one or more nozzles for supplying extinguishing agents fixed horizontally on one or two sides of the input unit at an angle selected from the condition of directionality of the jets of fire extinguishing substances along the tank wall; nozzle axles fixed on opposite sides of the input unit are located in parallel horizontal planes; the input unit is made of a material with strength characteristics exceeding the strength characteristics of the upper tank belt, and the tank roof, the lid of the input unit and its attachment to the unit are made of material with destructive characteristics lower than the destructive characteristics of the walls of the input unit and the upper belt of the tank - RU 2334532 C2, 2008

Sign, which is common with the proposed method, is the supply of foam-generating trunks placed along the perimeter of the tank from above, on the inner surface of the tank at least 2 jets of extinguishing agent - foam.

The disadvantages of this method are to use simultaneously with the foam consumable components in the form of powder and neutral gases, complicating the design; extinguishing by the method of draining the foam from the walls of the tank to the surface of the flammable liquid, which significantly increases the time to extinguish the fire, which is a determining factor affecting the stability of the supporting structures of the tank; in installation on the tank structure of additional systems and devices, which should have a huge reliability resource, which is one of the main problems of all stationary fire-fighting equipment installed on tanks.

In connection with these drawbacks, the technical problem solved by the invention is to create a method of extinguishing fires on large tanks with flammable liquids and liquid gases by increasing the efficiency of the extinguishing process while simultaneously changing the known technology and devices used to implement it.

The technical result that can be obtained is to extinguish fires on large tanks with the effective use of a fire extinguishing agent and a decrease in the time of fire extinguishing.

The problem is solved due to the fact that in a known method of extinguishing a fire in tanks with flammable and combustible liquids by feeding from foaming generating trunks N≥2 placed around the perimeter of the tank from above, on the inner surfaces of the tank jets of extinguishing agent, foam is jets on the surface of flammable liquid the tank by scanning in the vertical and horizontal planes by software-controlled or oscillating foam-generating shafts in the sector allocated for each trunk from couple foam coating the entire surface; foam is supplied according to the fire extinguishing control program from the tank wall synchronously with all foam generating trunks, gradually moving towards the center of the tank and tangentially to the fire on the pre-cooled area; to build up to the desired thickness of the foam layer, the foam is served cyclically, moving in jets from the walls to the center and back to the walls of the tank; fire extinguishing control program is corrected by the coordinate IR sensors installed on the foam generating trunks or quadrolet, according to the coordinates of the areas of the combustion centers; foam is used as a fire extinguishing agent with water mist; for foam supply, foam generating shafts are used to form foam with water mist; foam is served with an atomization angle of> 30 degrees at distances of up to 20 m and an atomization angle of <30 degrees at distances of more than 20 m, adjusting the angle of atomization of the nozzles that make up the foam generating trunks, depending on the angle of elevation of the trunks; foam generating trunks are taken out of the tank, and foam is supplied from a distance of> 2 m in the horizontal plane from the side of the tank;

Foam-generating software-controlled shafts installed on the ground for the ramp (option).

Signs of the proposed method, distinctive features of the method according to the prototype: foam is jetted to the surface of the combustible liquid of the reservoir by scanning programmatically or oscillating foam-generating barrels in the sector allocated for each barrel based on foam coverage of the entire surface; foam is supplied according to the fire extinguishing control program from the tank wall synchronously with all foam generating trunks, gradually moving towards the center of the tank and tangentially to the fire on the pre-cooled area; to build foam, foam is fed cyclically, moving by jets from the walls to the center and back to the walls of the tank; fire extinguishing control program is corrected by the coordinate IR sensors installed on the foam generating trunks or quadrolet, according to the coordinates of the areas of the combustion centers; foam is used as a fire extinguishing agent with water mist; for foam supply, foam generating shafts are used to form foam with water mist; foam is served with an atomization angle of> 30 degrees at distances of up to 20 m and an atomization angle of <30 degrees at distances of more than 20 m, adjusting the angle of atomization of the nozzles that make up the foam generating trunks, depending on the angle of elevation of the trunks; foam generating trunks are taken out of the tank, and foam is supplied from a distance of> 2 m in the horizontal plane from the side of the tank; Foam-generating software-controlled shafts installed on the ground for ramping.

The supply of foam jets to the surface of the flammable liquid of the reservoir by scanning in vertical and horizontal planes using software-controlled or oscillating foam-generating barrels allows you to quickly move the foamy jet in the sector reserved for each barrel based on the foam coverage of the entire surface of the tank; due to the fluidity of the foam, but mainly due to the hydromechanical effect of the jet. The supply of foam according to the fire extinguishing control program to the wall and from the tank wall synchronously with all foam generating trunks, gradually moving towards the center of the tank with respect to the fire on the area pre-cooled by foam, allows uniform feeding of foam over the area, without coming into direct contact with fire, thereby reducing the destruction of foam from contact with fire, the center of ignition is gradually tightened with increasing irrigation intensity to the center, and the hydromechanical effect of the jet in one direction creates T circular movement of the foam tank, carrying out rapid filling of its perimeter surface. Since the foam is destroyed during extinguishing, and the foam layer on the surface becomes thin, which can lead to repeated emissions of fire, the thickness of the foam layer is increased, for which the foam is fed through the scanning program cyclically, shifting from the walls to the center and back to the tank walls. The fire extinguishing control program is corrected by coordinate IR sensors installed on foam generating trunks or quadrolet, according to the coordinates of the areas of the combustion centers, this allows you not to make passes of fire when scanning and move to the next section after reaching the required thickness of the foam layer. It should be noted that usually in conditions of smoke and inaccessibility for viewing the surface of a combustible liquid, fire extinguishing is carried out all over the tank “blindly” and therefore with low efficiency. Use as a fire extinguishing agent foam with water mist allows you to increase the distance of the foam jet, increases its fluidity, because residual water in the foam under shock load is rapidly transferred to the lower layer when falling, giving the foam increased fluidity, in the upper layer a stable foam is formed with an average bubble diameter d = 0.5 mm with a multiplicity of Kp = 30-40. To supply such a foam, foam-generating barrels are used, which form a single-flow foam with sprayed water at the outlet of the barrel. Foam is supplied with an atomization angle of> 30 degrees at distances up to 20 m and with an atomization angle of <30 degrees at distances over 20 m, adjusting the atomization angle of the nozzles that make up the generating trunk, depending on the angle of elevation of the trunks, which allows more efficient use of the jet throughout the working area: use a compact jet having a high range in remote protected areas, and a jet with a wide angle of atomization at short distances, having a soft supply of foam, without bubbling hydro-mechanical action trui. Foam-generating trunks are taken out of the tank and the foam is supplied from a distance of> 2 m in the horizontal plane from the side of the tank, as a matter of fact, outside the zone of the blast wave to preserve the survivability of the system in the event of an explosion. In the variant of extinguishing technology “from the ground”, foam generating trunks installed on the ground behind the rampage allow using high rates of foam supply from the used trunks, minimizing the costs of fire extinguishing systems and their installation.

The authors are not known methods of fire extinguishing tanks with distinctive features in accordance with the claimed technical solutions.

The invention meets the requirements of novelty and positive effect, as well as the criterion of "significant differences".

FIG. Figure 1 shows a general view of a foam generating lafete trunk (DL), a plan-diagram of the installation of a drug on a tank, and a phased plan-scheme of extinguishing a fire.

The process of practical extinguishing of real fires, as a rule, is divided into two successive stages: the first - covering the entire free surface of a combustible liquid with a relatively thin layer of foam, reducing the intensity of a fire burning or breaking the fire into many individual burning foci; the second is the buildup of the required thickness of the foam layer, which completely reduces the concentration of combustible vapors above the foam layer below the lower concentration limit of ignition (burning) of the vapors of this combustible liquid.

For the implementation of the proposed new method of importance is the correct choice of foam generating devices. With the standard recommended method of extinguishing the GZh fires on large tanks using stationary and uncontrolled foam generators GPS 600 with Kp = 100 and foam jet length of about 6-8 meters, foam streams are fed directly into the fire flame, and the area of mechanical coating of the burning surface of the foam with foam does not reach more than 50-75% and further spreading of the foam does not occur, and the coefficient of destruction of the foam reaches with this 90-95%. This is explained by the fact that foam with a multiplicity of 100 has almost no fluidity, i.e. spreadability. And its heat capacity and fire resistance is 2.5 times less than that of foam with Kp = 40 and 5 times less than that of foam with Kp = 20. Therefore, with such parameters of the HPS 600 barrels and foam with Kp = 100, extinguishing the GZH fire on large tanks becomes technically impossible in principle, which is confirmed by the long-term practice of fire fighting. Therefore, from the practice of experiments and theoretical calculations of the process of extinguishing this type of fires, it is recommended to use a more effective homogeneous water-air foam with a multiplicity of Кп = 30 ± 10. This foam has a much greater specific heat (2-3 times more than foam Kp = 100) and, accordingly, the best cooling capacity of the surface layer of the burning liquid, which is one of the dominant characteristics in extinguishing this type of fire. In addition, this foam, having a much higher fluidity and fire resistance, compared with foam KP = 100, allows you to quickly cover the entire surface of the burning liquid with a primary layer. Both of these circumstances significantly - by 3-4 times - reduce the proportion of foam losses and the intensity of its losses from destruction in the process of extinguishing a fire, and 2-3 times increase the intensity of foam spreading over the surface of a burning liquid, thereby strengthening the extinguishing cooling mechanism and shielding and insulating extinguishing mechanisms. In the proposed fire extinguishing system on large tanks as foam generators, it is possible to use foam generators of a new type of high performance, providing complete coverage of the entire surface of the burning liquid with a foam layer in 1-2 minutes and effective fire extinguishing in 5-10 minutes on tanks of any size. This effect is achieved due to a sharp decrease in foam losses from its destruction in the process of extinguishing a fire: in total up to 40-50% and even less.

Fire foam barrel medium multiplicity UKTP “Purga 10.20.30” produced by LLC NPO SOPOT is capable of implementing the required foam multiplicity parameter Kp = 30 ± 10, as well as the range of supply of foam jets of 30-50 m and more and the ability to control the direction of their flow that allows you to increase the fire extinguishing rate by 5-10 times, reducing the time for extinguishing it to the standard values of about 10-15 minutes, and also - reduce the specific and total costs of fire extinguishing agents (OS) for extinguishing the fire, bringing them to regulatory costs and standard stocks (at times ka 3-fold) at all sites of storage of flammable liquids - combustible. However, this foam generator is quite expensive and complex in design. The use of water-air foam with dispersed water-sprayed water in the invention makes it possible to use other medium-foam foam generators with good ballistic characteristics, which are simpler in design, and their cost is much lower. In such a foam, the residual water under shock load in the fall quickly moves to the bottom layer, significantly increasing the fluidity of the foam. An example of such foam generator trunks are trunks of the type LS (D) -S40Usr, LS (D) -S60Usr, TU 4854-003-16820082, produced by LLC Engineering Center EFER. These trunks have the ability to adjust the angle of atomization of the supply of foam, which allows you to create a soft supply of foam for both near and long distances, without bubbling HZ hydromechanical effect of the jet.

With the selected method of controlled supply of foam to the surface of a combustible liquid, for example, the reservoir RVS-20000, foam generator trunks with a foam jet supply range of about 45-50 meters, and a foam jet spot surface area of about 64 m ² with 4 trunks, the total area of the initial foam spot is 64 × 4 = 256 m ² , and at a scan speed of 2-6 ° / s and the required angle of rotation of the barrel ± 45 degrees, the time of primary coating of the combustible liquid mirror with the minimum thickness of the foam layer is 40-60 seconds, t. e. about 1 min. With the selected multiplicity of foam Kp = 40 and the selected feed rate of the OS Ip river = 0.145 l / m ² ⋅s, without taking into account foam losses from destruction and the multiplicity of foam in the process of extinguishing a fire, the growth rate of the foam layer on the surface of the combustible liquid Vps calculated = In rivers × Kn = 0.145 × 40 = 5.8 mm / s, which is quite satisfactorily confirmed by cold imitation of the extinguishing process (supply of foam to the surface of the liquid gas without a burning process). By accepting the conditionally required thickness of the foam layer on the surface of crude oil equal to N p tr = 0.5 m (for foam multiplicity Kp = 30-10, it can be reduced to 20-25 cm), the time to increase the required thickness of the foam layer is t n = H nrr / Vnf rasc = 500 / 5.8 = 86.2 s or about 1.44 min.

The theoretical and theoretical time for extinguishing the fire under consideration is tt, equal to the time it takes for a mirror of combustible liquid to be covered with a layer of foam of the minimum thickness tpokra, plus the time it takes to build up the required thickness of the layer of foam tn.sl., tt = 1 + 1.44 = 2.44 or about 3 minutes.

But when extinguishing real fires, the whole problem is in the share of OS losses in the extinguishing process. And taking into account the OS losses due to a decrease in the actual OS supply intensity to the fire center from the evaporation of a part of the solution supplied to the fire extinguishing by 50% and losses from foam destruction in the process of fire extinguishing, reaching 50% of the quantity fed and reducing its multiplicity under the influence of destructive factors by 50% , to Kpf = 20, the actual rate of growth of the foam layer Vn SL f decreases to Vn SL f = If × Kp f = 0.145 × 0.5 × 20 = 1.45 mm / s. Then the time to build up the foam layer of the required thickness will increase to tn n SL f = 500 / 1.45 = 345 s or approximately 5.75-6 minutes. And the time it takes for the mirror to cover the surface of a flammable liquid with an initial layer of foam also increases about 3-4 times, i.e. up to 3 - 4 minutes. And, accordingly, the total time of extinguishing the fire will be approximately 8-10 minutes. The fire extinguishing efficiency indicator on the tank is equal to: Pat = Fp / Voc × tt, where Fp is the fire area (m ² ), Voc is the volume of the foaming agent solution spent on extinguishing (l or m ³ ), and tt is the fire extinguishing time ( sec or min). Pat = 1667/144 × 10 = 1.16 (m ² / m ³ min).

A new method of extinguishing a fire will be considered in the tank protection scheme in FIG. 1a, 1b. Along the perimeter of the tank 1 filled with flammable liquid 2, over the tank 1 and at distances> 2 m from it are installed foam generating software-controlled firearm trunks (B) 3 on brackets 4 attached to tank 1 connected by risers 5 to the ring fire water supply system 6 to the main pipeline supplying the foaming agent solution 7. The trunks 3, having high rates in range, can be installed on the ground behind the dumping (not shown in the diagram), minimizing the costs of fire extinguishing systems and their installation. In this case, the ballistic fire extinguishing program is adjusted using mounted jets. A general view of the software-controlled lafet trunk 3 is shown in FIG. 1g. The barrel 3, which forms the foam with sprayed water, is made in an explosion-proof version with a spherical drive of vertical movement 8 and a drive of horizontal movement 9. Adjustable nozzle 10 has a drive for adjusting the angle of spraying 11. The trunk 3 is attached to the stand 4 through a flange connection 12. On the trunk 3 is installed matrix IR sensor 13, working in a smoke environment, issuing the coordinates of areas of the fires.

On a fire signal, when the signal is confirmed by the operator of round-the-clock duty, the control signal is sent to the fire extinguishing software control device (not shown), which forms a command for foam extinguishing of the HP 3. All the LAN 3 are simultaneously switched on, and the foam starts to flow in the surface of the combustible fluid of the reservoir is scanned in a vertical plane by a drive 8 and a horizontal plane by a drive 9. LS 3 quickly move foam streams in the sector reserved for each barrel from the calculation covered I foam entire surface of the tank, the foam on the surface of the movement is not only due to the fluidity of the foam, and is mainly due to the impact of hydro-mechanical jet. The foam is supplied according to the fire extinguishing control program to the wall and from the tank wall synchronously from all foam generating trunks, gradually moving towards the center of the tank relative to the fire on the pre-cooled foam area, which allows to uniformly deliver the foam over the surface area of the flammable liquid without practically feeding the foam directly into fire flame (except for the first, most initial, stage of extinguishing a fire, when the first parts of the surface of a burning liquid are released from burning), thereby reducing Rushen foam from contact with the fire. Scanning in a vertical plane at the first stage, see the step-by-step plan for extinguishing a fire in FIG. 1b, 1g, 1d, 1e of a flowable foam, driven by the hydromechanical action of the jet, allows the tank wall to be cooled and the tank's near-wall zone reclaimed from the fire, see FIG. 1c. The area of combustion gradually decreases with increasing irrigation intensity towards the center of the tank, see FIG. 1d, 1d, and the hydromechanical effect of the jet in one direction creates a circular motion of the foam through the tank, carrying out a rapid filling of the protected surface with it, see FIG. 1e. Since the foam is destroyed during extinguishing and the foam layer on the surface becomes thin, which can lead to repeated emissions of fire, at the final stage, see FIG. 1e, the foam is increased according to the program from the program control device (not shown in the diagram), for which the foam is supplied according to the scanning program cyclically, moving by jets from the walls to the center and back to the walls of the tank. The fire extinguishing control program is corrected by coordinate IR sensors 13 installed on the foam generating trunks 3 or quadrolet, according to the coordinates of the areas of the burning centers, this allows you to skip fires during scanning and move to the next section after the required thickness of the foam layer is reached on the steamed part of the surface flammable liquid. The foam atomization angle is formed by the nozzle 10 and is automatically controlled by the drive 11: foam is supplied with an atomization angle of> 30 degrees at distances of up to 20 m and an atomization angle of <30 degrees at distances of more than 20 meters. After the start of a foam attack in 2-3 minutes of extinguishing, the intensity of burning (and the height of the flame) the fire gradually begins to decrease, and after another 5-7 minutes the fire stops completely.

The fire service arrives at the fire site after 2-3 minutes. Since the trunks have a remote control, the fire manager can make corrective actions to the fire extinguishing program through the remote control (not shown in the diagram).

The general physics of the processes occurring when extinguishing fires from the ground is similar to that described above for the first option, but when fire extinguishing foam is supplied by the gun trunks from the ground level by mounted streams, through the hot zone of combustion products and through the thickness of the fire flame, the foam destruction coefficient increases to 75%, therefore, in order to obtain the required quenching effect, the feed rate of the waste must be increased to 0.15-0.5 l / m ² ⋅s. Due to the deterioration of the conditions for supplying foam to the fire center (through the tank side with mounted jets) and increasing the intensity of foam destruction from supplying it through the fire flame, the time of primary coating of the surface of the combustible liquid with a continuous foam layer will increase. At the same time, it should be noted that in automatic extinguishing mode and when foam is supplied from the ground level, time is removed for the deployment of technical equipment and for combat work to raise the firearms to the height of the tank side (12-18 m.) will decrease after covering the extinguishing wall with foam. The time of the primary coating of the GJ mirror with the primary foam layer, taking into account the action of all the factors destroying the foam, is approximately 5-6 minutes. The time will also increase at the stage of increasing the required thickness of the foam layer, since With this method of supplying fire extinguishing foam to the surface of a combustible liquid, the proportion of its destruction in the process of extinguishing increases to 80%, and the actual ratio of foam to the end of the extinguishing process will decrease to Kp = 8. Accordingly, the growth rate of the foam layer to the desired height (thickness) will decrease. Positive in the new method is the use of hydromechanical impact of the jet and circular rotation for the rapid movement of foam through the tank, as well as the use of foam with high fluidity, which reduces the time it takes to fill the tank with foam. The time to build up the required thickness of the foam layer will increase to about 7-9 minutes, and the time to extinguish the fire when supplying controlled foam jets from the ground will be about 15 minutes. This is the limit of the permissible standard time (15 min), but such an indicator of the time of extinguishing of practically un extinguished fires on large tanks is a significant achievement.

The required number of foam generating lafet trunks installed on one tank and their consumption is determined by the calculation method at the feasibility study stage of the project, based on the estimated economically feasible fire extinguishing time in accordance with GOST 12.1.004, SNiP 2.11.03-93, tank volume and the intensity of the supply of extinguishing agents for cooling and extinguishing.

The proposed method of extinguishing a fire provides a high degree of reliability of protection of the tank against destruction due to:

- reducing the time of fire to a value below the critical value leading to the destruction of the supporting structures of the tank;

- simultaneous cooling of the tank wall along its entire circumference and extinguishing a flammable liquid.

The proposed method and device will allow:

- to prevent the risk of causing harm to the population, the environment, animals and plants in case of fire defined by the regulations or the contract;

- reduce the costs of enterprises to eliminate the consequences of a fire;

- reduce the recovery time tanks for their further use;

- prevent the development of emergency situations;

- to ensure the suppression of any flammable and combustible liquids in tanks of all sizes, with and without thermal insulation;

- reduce the number of fire fighting equipment used to extinguish a fire, and the number of personnel of rescue teams and services;

- reduce the risks and duration of damaging factors on the personnel of the emergency services, the supporting structures of the tank and the environment.

Claims (9)

1. The method of extinguishing fires on large tanks with flammable and combustible liquids by feeding from foam-generating trunks N≥2, placed along the perimeter of the tank from above, on the inner surfaces of the tank jets of extinguishing agent, in which the foam is jetted onto the surface of the flammable liquid in the tank vertical and horizontal planes by software-controlled or oscillating foam-generating shafts in the sector reserved for each barrel from the calculation of foam coverage throughout overhnosti flammable liquid. 2. A method according to claim 1, characterized in that the foam is supplied according to the fire extinguishing control program to the wall and from the tank wall synchronously from all foam generating trunks, gradually shifting to the center of the tank and tangentially to the fire on the pre-cooled foam section. 3. The method according to p. 1, characterized in that to build up a layer of foam to the desired thickness of the layer serves the fire extinguishing control program from the tank wall synchronously with all foaming generating trunks, gradually shifting to the center and back to the tank walls cyclically. 4. The method according to paragraphs. 1 and 2, characterized in that the fire extinguishing control program is corrected by coordinate IR sensors installed on the foam generating shafts or quadrolet, according to the coordinates of the areas of the fire centers. 5. The method according to p. 1, characterized in that as a fire extinguishing agent used foam with water mist. 6. The method according to paragraphs. 1 and 5, characterized in that for the supply of foam using foam generating trunks, forming a foam with water mist. 7. The method according to p. 1, characterized in that the foam is served with an atomization angle of> 30 degrees at distances up to 20 m and an atomization angle of <30 degrees at distances over 20 m, adjusting the spray angle of nozzles that make up the foam generating shafts, depending on the angle of elevation of the trunks. 8. The method according to p. 1, characterized in that the foam generating trunks are taken out of the tank and the foam is supplied from a distance of> 2 m in the horizontal plane from the side of the tank. 9. The method according to p. 1, characterized in that the foam generating trunks installed on the ground for ramping.

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