RU2345806C2 - Method of surface forest fire containment - Google Patents

Abstract

FIELD: agriculture, forest fire.

SUBSTANCE: method of surface forest fire containment involves creating a counterfire belt of burnt forest fuels in front of the fire front and fixing its outer boundary. Forest fuels are burnt by a high-temperature supersonic gas jet which is generated as an axisymmetric or flat one. The counterfire belt boundary is fixed by the low-temperature jet of water which is supplied simultaneously with the high-temperature jet to the external counterfire belt edge in respect to the fire front. Angle ψ between the centre lines of the jets is chosen so that to prevent overlapping of the contact areas between the high- and low temperature jets and the forest fuels surface; in particular ψ≥arccosH/L₁-arccosH/L₂ where H stands for the average height from the treated surface to the high- and low temperature jet sources, L₁, L₂ - the range of the high- and low temperature jets respectively.

EFFECT: increasing efficiency and safety of creating a supporting belt for the containment of forest or steppe surface fire.

3 cl, 1 dwg

Description

The invention relates to the field of environmental protection, and in particular to methods of extinguishing forest and steppe fires.

Known methods for localizing forest fires by creating fire protection strips. The Research Institute of Fire Protection of Forests and Forestry Mechanization offers a method in which support strips (plow the soil) are laid parallel to the fire front, followed by ignition of ground combustible materials behind them (Auth. St. No. 1806791, А62С 2/00, 1991). The method is time consuming and requires the presence of roads near the fire.

A known method of localizing forest fires by annealing (burning) combustible materials in front of the fire front, which uses high-temperature gas jets (Pat. SU No. 1147413. Method of localization of forest fires, MKI A62C 1/00. Publ. 1985.03.30).

The known method is not effective enough, because combustion in the annealing strip has the ability to spread towards the firefighting operator.

Closest to the proposed solution is a method using high temperature and low temperature gas flows. The method is based on the annealing of forest combustible materials (LGM) by a high-temperature gas jet with exposure to the edge of the annealing strip closest to the operator with an auxiliary low-temperature gas jet with a temperature below the ignition of the LGM (Petrakov V.M. et al. Method for localizing a forest fire. Pat. RF RF No. 2113260, А62С 3/02. Publ. 1998.06.20). Selected as a prototype.

In the prototype method, a high-temperature gas stream from a flamethrower or a jet stream of a gas turbine engine is supplied to the LGM annealing zone and the material is annealed to form a non-combustible mineralized strip. The annealing of the boundary of the annealing strip external to the fire front is fixed by a low-temperature gas flow. By supplying an auxiliary gas stream, the reacted LGMs are blown off towards the front of the fire. Thus, a supporting (protective) strip is created that prevents further spread of the fire front.

A significant disadvantage of the prototype method is the inability to carry out simultaneous local effects on the treated surface of the working (annealing) and auxiliary (fixing) gas jets. The flows of the main and auxiliary gas jets are mixed due to the turbulent nature of the flow. In this case, the temperature of the high-temperature gas jet decreases, since part of its thermal energy is spent on heating the auxiliary gas jet. Accordingly, the annealing efficiency decreases, and the cost of localizing the fire increases. When a fire is localized using LGM annealing, the boundary of the annealing band should be clearly fixed. Using the installation of gas-dynamic quenching (UGDT) as a source of auxiliary jet, as proposed in the prototype, does not exclude the possibility of ignition of the auxiliary reference strip. According to the prototype method, the gas stream has a high temperature, up to 500-700 ° C at the exit of the UGDT nozzle, and only works effectively when the UGDT is removed over a considerable distance, which reduces its temperature to values below the ignition temperature of the LGM. Essentially, the fixation of the outer edge of the annealing strip in the prototype method is carried out by extinguishing secondary foci of combustion caused by a high-temperature gas stream. The processes of forming an annealing strip and fixing its outer boundary are separated both in time and geographically, which requires the participation of an additional fire fighting operator. In addition, when fixing the support strip using a gas jet, it is possible not only to blow off the reacted LGM residues towards the fire front, but also to “blow” them in the annealing zone, for example, of peat sections, i.e. there is a possibility of the spread of LGM burning towards the operator, which reduces the safety of fire fighting. These deficiencies should be addressed.

The objective of the invention is to increase the efficiency and safety of localization of a forest fire using annealing of forest combustible materials.

The problem is solved in that, in addition to the main features of the prototype method, fixing the mentioned boundary is carried out simultaneously with the formation of the annealing strip, moreover, a low-temperature jet is formed from liquid and directed to the edge of the annealing strip of forest combustible materials external to the fire front, and the angle between the geometrical axes of the aforementioned jets are chosen so that the areas of interaction of the jets with the surface to be treated do not overlap. This ensures the efficient use of the energy of a high-temperature supersonic jet and a clear fixation of the outer annealing band border, which is closest to the operator. A low temperature jet can be obtained, for example, from water with additives. The flow may be continuous, annular or atomized.

The essence of the method is illustrated in the drawing. Here 1 is the processed (underlying) surface of the LGM; 2 - high-temperature supersonic gas jet; 3 - axisymmetric or flat nozzle; 4 - confuser nozzle; 5 - annular or atomized stream of liquid; 6 - edge of the annealing strip; 7 - annealing flame torch; 8 - front of the bottom forest fire; 9, 10 - geometric axis of the jets.

As can be seen in the diagram, for some effective value of the angle ψ, the area of influence on the treated surface of the auxiliary jet s1 and the high-temperature gas jet s2 do not overlap.

The method is implemented as follows.

A supersonic jet 2 is formed from a source of high-temperature gases, for example, from a device according to the RF certificate for utility model No. 12975, the jet is directed to the annealing zone, the LGM is ignited on area s2 and, moving it parallel to the fire front, an annealing strip is formed. At the same time, using a confuser nozzle 4, a liquid stream 5 is formed, which is directed to the LGM surface at a certain angle ψ to stream 2. They act by the low-temperature stream on the edge of the annealing strip closest to the operator on the area s1 and, moving it parallel to the annealing strip, create a non-combustible support strip, fixing the annealing boundary. Due to the formation of a dense low-temperature flow, the jets are spatially separated and do not intersect; there is no turbulent mixing. Since the areas s1 and s2 do not overlap, the thermal energy of a supersonic high-temperature gas jet is completely spent on annealing the LGM towards the front of the fire, while the liquid jet irrigates the near layer of the LGM and prevents the spread of fire towards the operator. The efficiency of the formation of a mineralized strip, and hence the annealing process, will be higher than in the prototype method, which can be proved by thermodynamic calculations [4] and empirically, and the process of localizing the fire is safer.

In order to increase the annealing zone, in addition to the indicated features, a high-temperature gas jet can be formed flat.

It is advisable to know in advance the approximate value of the angle between the jets as a parameter of the device, and not to choose it during the annealing. Calculations show that at real (practical) distances from the sources of the jets to the treatment site, it can be accepted with an acceptable error (8-10%) that the height of the nozzles above the soil level is approximately the same, H ₁ = H ₂ , and the distance between the nozzles is much less range of jets. The value of the angle ψ at which the areas s1 and s2 do not overlap with each other can be determined from the condition ψ≈arccosH / L ₁ -arccosH / L ₂ , where H is the average height from the treated surface to the nozzles of the sources of high temperature H ₁ and low temperature H ₂ jets , Н = 0.5 (Н ₁ + Н ₂ ), L ₁ , L ₂ - range of high-temperature and low-temperature jets, respectively. This feature does not exclude the possibility of adjusting the optimal angle at the fire site.

Example. The fire is localized using a mobile installation containing twin sources of both high-temperature and low-temperature jets. The jets are directed into the annealing zone at an angle ψ to each other, depending on the power of the sources. To estimate the angle ψ, we take the gas temperature at the source exit T ₀ = 1610 K, the ambient temperature T _H = 293 K, the ignition temperature of the LGM T = 693 K, and choose the radius of the critical section of the nozzle R ₀ = 5 × 10 ^-3 m. The distance L ₁ , or the length of the jet at which the ignition temperature is set, according to the known thermodynamic formulas for axisymmetric and flat jets [3], will be L ₁ = 2.5 m. At a height of H = 1.8 m (operator height), the angle ψ = φ ₁ -φ ₂ = 47 ° -37 ° = 10 °. Therefore, if the axis of the jets is directed at an angle ψ = 10 ° or more to each other, the jets do not intersect, and the areas s1 and s2 of contact between the jets and the surface being treated do not overlap.

You can evaluate the geometric parameters of the reference strip. So, the width of the strip processed by the liquid is approximately equal to Δ ₁ ≈r ₁ + r ₂ ≈0.32 m. If you use a water tank with a volume of 0.05 m ³ and irrigate LGM with an even layer with a depth of 1 · 10 ^-3 m, then the length the processed LGM strip will be, without taking into account evaporation, about 150 m. The width of the mineralized strip created by a high-temperature supersonic gas jet for an axisymmetric nozzle will be Δ ₁ ≈r ₃ + r ₄ ≈0.49 m. If you use a flat nozzle and form a plane jet, the ignition bandwidth with the same processing parameters will increase to 0 , 53 m. More detailed calculations show that the efficiency of creating an annealing strip by the action of a flat gas jet is higher compared to an axisymmetric jet (bulky calculations are omitted). The operation parameters of a powerful annealing installation that implements a method, for example, installed on an all-terrain vehicle, are determined similarly.

The example shows that this method of localization can be implemented in practice, which indicates the compliance of the invention with the criterion of industrial applicability. Improving the efficiency of annealing LGM with a combination of the claimed features is not obvious, which indicates the conformity of the technical solution to the criterion of inventive step. Currently, a test installation is being designed to implement the method in natural conditions.

Information sources

1. Pat. RF 2113260, А62С 1/22. The method of localization of a forest fire / Petrakov V.N., Konyaev E.A., Galaev D.V. Publ. B.I. No. 17 (part II), 06/20/98.

2. Certificate of the Russian Federation for utility model No. 12975, BI No. 8, 2000.03.20.

3. A collection of problems on the theory of combustion. Textbook for universities / Ed. Pomerantseva V.V. L .: Energoatomizdat, 1983. 152 p.

4. Grishin A.M. Mathematical modeling of forest fires and new ways to deal with them. Novosibirsk: Nauka, 1992. 407 p.

Claims (3)

1. A method for localizing a downstream forest fire, including exposing a surface with forest combustible material to a high-temperature supersonic gas jet, creating a reference mineralized annealing strip and fixing the boundary of the annealing strip with a low-temperature jet having a temperature below the ignition temperature of combustible forest materials, characterized in that fixing the said boundary carried out simultaneously with the formation of the annealing strip, and the low-temperature jet is formed from a liquid and direct it to the edge of the annealing band of forest combustible materials external to the fire front, and the angle between the geometric axes of the said jets is chosen so that the areas of interaction of the jets with the treated surface do not overlap. 2. The method according to claim 1, characterized in that the high-temperature supersonic gas stream is formed flat. 3. The method according to claim 1 or 2, characterized in that the angle ψ between the geometric axes of the high temperature and low temperature jets is selected from the ratio:
ψ≥arccosH / L ₁ -arccosH / L ₂ ,
where H is the average height from the treated surface to the sources of high temperature and low temperature jets; L ₁ , L ₂ - the range of high-temperature and low-temperature jets, respectively.