RU2367491C1 - Method of fighting forest fire - Google Patents

Abstract

FIELD: fire-fighting equipment.

SUBSTANCE: fireproof band is formed ahead of fire front. Mix of inert gas with aerosol is fed into said band. Note that turbojet engine exhaust gases represent inert gas, while aerosol represents powder of fire resistant particles. Proposed invention aims at supplying unlimited amount of fuel to inert gas source and holding inert gas in the limits of aforesaid fireproof band till fire front reaching it. Note that pyrolignite of lime is used as turbojet engine fuel, missed with compressed air in two-chamber feeder and sent into turbojet engine combustion chamber. Note also that aerosol particle size is selected to allow particles hovering in inert gas upward flow until fire front arrival.

EFFECT: unlimited amount of accessible combustibles, inert gases, fire proof aerosols and fire suppressing materials.

3 ex

Description

The invention relates to fire fighting equipment, and in particular to methods of containing fire, mainly in forest fires.

Forest fires usually spread in the form of a fire front, most often moving in the wind. A known method of extinguishing such a fire is to create a barrier strip in the path of the fire that impedes the progress of the fire. Non-combustible materials may be used as an obstacle or forest species removed.

Known as non-combustible materials that create an extinguishing medium, inert gases. So, the stationary Saupig installation, which emits liquid nitrogen, and the mobile Sturm, are known, see RF patent No. 2050865. However, the power of both installations is insufficient to suppress large fires. So, the Saupig installation has a stock of liquid nitrogen in the amount of 10 tons, and the Sturm installation has only 6 tons.

Also known is a fire extinguishing installation using an air-jet engine to supply a water-air extinguishing mixture, see RF patent No. 2236876.

As an inert gas generator, used aviation gas turbine engines (GTE) are used. Known aviation gas turbine engine used to extinguish fires in the oil and gas fields, see RF patent No. 2039212.

Currently, many extinguishing agents used contain aerosols that are delivered to the combustion site with an inert gas and contribute to the absorption of heat and oxygen when mixed with combustion products. However, a significant part of aerosols is produced by burning solid fuel (powder) charges.

Known, for example, is a method of generating an inert medium by burning solid fuel with the release of aerosols of alkali metals according to the patent of the Russian Federation No. 20055516. A known method of producing powder gases with aerosols of solid inhibitors according to the patent of the Russian Federation No.2019214. There is also known a method of producing powder gases with aerosols according to the patent of the Russian Federation No. 2078599.

There is also a method of extinguishing a fire according to the patent of the Russian Federation No. 2102093, according to which an inert foam of medium multiplicity is obtained. After displacement of the foam with pyrotechnic gas, an inert foam of high multiplicity containing an aerosol is obtained.

The use of aerosols in the form of fire-resistant powders delivered to the combustion zone by throwing is known, see RF patents No. 1818107 and No. 2027452, with a quenching spray, see RF patent No. 2036674.

There is also known a method of extinguishing a fire according to the patent of the Russian Federation No. 2100302, according to which fire-resistant particles are fed into the burning area, the sizes of which are taken from the calculation of the particles hanging or weighing in the upward flow of combustion products.

A known method of extinguishing a fire with a jet engine turbojet engine, see RF patent No. 2130793. The method of operation of this installation is taken as a prototype of the invention.

In large-scale forest fires, tens and hundreds of tons of combustible materials are required to produce inert gas. The disadvantage of this method is the strict limitation of combustible materials. Their delivery to the forest fire area most often becomes problematic. At the same time, the lack of combustible materials extremely limits the amount of fire extinguishing medium produced, which does not allow it to withstand the power of the fire.

Another disadvantage of the known fire extinguishing method is the dilution with air and the entrainment of the extinguishing medium from the fireproof strip until the approach of the fire front.

The aim of the invention is to eliminate these drawbacks, providing an unlimited supply of combustible materials to obtain the necessary amount of extinguishing medium and ensuring its retention within the fireproof strip until the front of the fire approaches it.

This goal is achieved by the proposed method of extinguishing forest fires, mainly strong, propagating in the form of a fire front, along which a fire-retardant strip is created in front of the fire front, into which a mixture of inert gas with aerosol is supplied, while the exhaust gases of the turbojet engine are used as inert gas, and powder of fire-resistant particles is used as an aerosol.

The essence of the invention lies in the fact that wood fuel is used as fuel in the turbojet engine, which is mixed in a two-chamber feeder with compressed air and fed into the combustion chamber of the turbojet engine, and the sizes of aerosol particles are taken from the calculation of their freezing in an upward flow of inert gas before the fire front .

Wood is a good fuel, the reserves of which are not limited at the place of the fire. The calorific value of dry wood is close to the calorific value of brown coal, its ash content is insignificant (1.5-2%). The moisture content of raw wood is about 30%, but this moisture is useful when burning fuel. However, conventional solid fuel combustion technologies are unsuitable for forest fire conditions. Typically, coal and wood are burned in a dense or fluidized bed or in crushed form in an open torch of a furnace. The analysis of these schemes reveals significant shortcomings, first of all, the low productivity of a unit volume of the reactor volume and uneven combustion.

More perfect is the combustion of solid fuel in a flow chamber at high pressure. Efficient atomization and burning of solid fuels requires finer grinding of materials than for burning them in a fluidized bed or an open flame. For grinding materials used ball, roll, disk, jet mills and other units. Dusty wood can be harvested in forests as inexpensive and renewable phyto-fuel. The same equipment can be used directly at the scene of a fire.

The combustion of pulverized fuel in the LRE flow chamber was used as far back as the 60s of the last century, see “The Small Encyclopedia“ Cosmonautics ”, page 266,“ Metal-containing Fuel ”and page 362,“ Pseudo-Liquid Fuel ”, ed. “Soviet Encyclopedia”, Moscow, 1970. To feed the turbojet engine into the combustion chamber, wood powder or phyto-fuel is mixed with compressed air from the compressor in a two-chamber feeder and fed into the combustion chamber as a pseudo-fluid medium. Phyto fuel is introduced into the combustion chamber through nozzles and burned with air supplied from the turbojet compressor. To reduce the temperature of the combustion products, phytofuel is burned with a lack of oxygen. The ash remaining after the combustion of the pulverized particles of wood has a submicron fineness and is not dangerous for the turbine blades. Inert gas with excess pressure is obtained after the turbine turbojet engine in the form of exhaust gases.

As an aerosol, inert gas is mixed with crushed clay or soil particles obtained at the fire site or harvested at the bases. After grinding clay, its powder is separated into fractions in known aerodynamic separators, see RF patents Nos. 2102113, 2102114, 2122887 and others.

The sizes of the hanging aerosol particles are determined based on the calculated thrust of the upward flow of inert gas. When inert gas is supplied to the volume of the fire-retardant strip, the hanging aerosol particles make the inert gas heavier and keep it near the ground as heavier than air. The sizes of the hanging particles are in the range of 10-50 μm depending on the time of approach of the fire front. The concentration of freezing aerosol can reach 2 kg / m ³ inert gas. Aerosols are mixed with an inert gas using a fan or ejector. After mixing, the temperature of the inert gas decreases, which is taken into account when calculating the supply of extinguishing medium (OGS).

OGS is fed to separate short sections of the fire-retardant strip by sequentially moving the gas turbine engine on board the all-terrain vehicle and distributing the OGS along prefabricated or inflatable pipes installed in two directions from the gas turbine engine. OGS is distributed over a short section of the strip, uniformly releasing it through the holes in the pipes and maintaining the speed of its flow through the pipes due to a gradual decrease in their diameter. Telescopic design of prefabricated pipes simplifies their storage and transportation. Before the approach of the fire front, a fire extinguishing medium shaft is formed in all sections of the fireproof strip.

The technical result of the invention is the production and use of new large-scale means for fighting forest fires, including accessible and unlimited combustible materials, inert high-pressure gases, fire-resistant aerosols and extinguishing media with specified tactical properties. Another technical result of the invention is the possibility of using wood as a new pseudo-liquid fuel for a wide range of applications: in gas turbine, diesel, steam-powered plants and engines. In addition, the proposed invention can be used to combat terrorists and the enemy by creating protective lanes and obstacles to the movement of military equipment and manpower.

The invention is illustrated by examples.

Example 1. A ground fire in a damp forest spreads along a 12 km front in the wind at a speed of 3 km per day. The firing line is chosen at a distance of 6 km from the front, taking into account the strip of light forest. During the first day, a fire-retardant strip with a width of 15 m and an access road are cleared and laid. At the same time, at a support base near the strip, they cut down the forest and produce phytofuel, extract clay in the quarry and produce freezing dust.

Over the next day, they produce OGS and fill it with a fireproof strip. A gas turbine engine converted from a TV3-117 engine of the Mi-8 helicopter is moved along a strip divided into 12 short sections. Prefabricated pipelines are transferred to the new section. During the operation of a gas turbine engine, the consumption of compressed air is 10 kg / s, the consumption of phytofuel at a humidity of 30% is 3.0 kg / s. During the day, the gas turbine engine generates 1.25 mln.m ^{3 of} inert gas, which forms an OGS shaft of 10 m wide and 10 m high on the fireproof strip. To keep the OGS in the strip, 600 tons of aerosol with a fineness of 15-20 microns are mixed with inert gas, cooling inert gas gas and freezing in the OGS for up to several days.

When approaching the fireproof strip of the fire front, the exhaust gas is sucked into the combustion zone by an upward draft. Due to the lack of oxygen, the power of the combustion centers decreases, as a result of which the temperature of the combustion products, the upward draft and the suction of air from the atmosphere decrease. Emissions of fire and smoldering parts of trees cannot overcome the shaft of the OGS. As a result, the fire stops and stops when burning materials burn out. When a fire is attenuated, a gas turbine engine can move along a strip to suppress individual fire breakouts. Conventional fire extinguishing media may be located behind the OGS shaft.

Example 2. A horse fire in a damp forest is propagated by a strong wind at a front of 20 km at a speed of 6 km per day. The firing line is chosen at a distance of 18 km from the front. During the first two days, they cut down the forest and lay a fireproof strip 20 m wide, an access road and a road along the entire strip. At the same time, on a support base near the strip, phytofuel is produced, clay is mined in the quarry, and the prepared phytofuel and aerosol are produced and imported.

Over the next day, they produce OGS and fill it with a fireproof strip. A gas turbine engine converted from a gas turbine unit GTU-10S of the compressor drive of a gas pumping station is moved along a strip divided into 10 short sections. Prefabricated pipelines are transferred to the new section. During the operation of a gas turbine engine, the consumption of compressed air is 45 kg / s, the consumption of phytofuel at a humidity of 30% is 13 kg / s. During the day, the gas turbine engine produces 5.6 million m ^{3 of} inert gas, which forms an OGS shaft of 20 m wide and 14 m high on the fireproof strip. To keep the OGS in the strip, 2800 tons of aerosol with a fineness of 15-20 μm are mixed into the inert gas.

When approaching the fireproof strip of the fire front, the wind is thrown into the OGS and the burning branches and coals go out in it. As the forest burns out in front of the OGS shaft, the ablation and emission of burning materials decreases. When a fire attenuates, a gas turbine engine can continue to operate.

Example 3. A strong fire in a dry forest spreads over several fronts with a total length of 50 km at a speed of 4 km per day. The firing line is chosen at a distance of 12 km from the fronts and a counter fire is launched, limiting its power by conventional means. During the first two days, the forest is burned out and a fire-retardant strip of 30 m wide is laid, as well as access and rear roads. At the same time, phytofuels and aerosol are harvested and produced locally at the rear support bases.

During the third day, they produce OGS and fill it with a fireproof strip. On the strip, divided into 5-6 smaller sections, 2 mobile gas turbine engines are installed, converted from the gas turbine unit GTU-20C of the compressor compressor drive. When transferring turbojet engines to another short section, prefabricated pipelines are also transferred there. During the operation of each gas turbine engine, the consumption of compressed air is 100 kg / s, the consumption of phytofuel at a humidity of 30% is 30 kg / s. During the day, two gas turbine engines generate 26 million m ^{3 of} inert gas, which forms an OGS shaft on a fire-retardant strip with a width of 30 m and an average height of 17 m. To keep the OGS in the strip, 8000 tons of aerosol are mixed into the inert gas.

When approaching the fire-retardant strip of fire, its power will be weakened by burning the forest with oncoming fire. Nevertheless, the thrust of the upward flow carries significant volumes of OGS into the combustion zone. Due to a lack of oxygen, the power of the remaining foci decreases, while the thrust of the upward flow disappears, as a result, the fire stops.

The present invention may have a wide scope. In the presence of low value wood on the ground, it can be used with the help of GRD-type installations for obtaining inexpensive thermal and electric energy. With the regular restoration of forest plantations, phytofuels become a widely available renewable energy source.

On the other hand, the use of OGS by this method makes it possible to severely limit the actions of a military enemy during ground and water combat operations. The use of OGS over a wide band or over an area allows you to block and squeeze out terrorists, rats, locusts and other pests from their shelters.

The proposed method can be applied to extinguish other types of fires: fountain, surface, peat, in closed volumes and others.

Claims (1)

The method of extinguishing forest fires, mainly strong, spreading in the form of a fire front, along which a fire-retardant strip is created in front of the fire front, into which a mixture of inert gas and aerosol is supplied, while the exhaust gases of a turbojet engine are used as inert gas, and powder is used as an aerosol fire-resistant particles, characterized in that wood fuel is used as fuel in a turbojet engine, which is mixed in a two-chamber feeder with compressed air and fed into the chamber Goran turbojet and the aerosol particle size is received from the calculation hang them in the upward flow of inert gas before the arrival of the fire front.