SU1134202A1 - Method of restricting the spread of forest fires - Google Patents

Abstract

A method for limiting the spreading of forest fires, including creating fire dampers in all the forests of the forest by spraying non-burning materials perpendicular to the direction of fire propagation, characterized in that, with the aim of improving the localization of high-level fires, materials that solidify on air are used to increase non-burning materials. ± 5% ata and

Description

The invention relates to methods for fighting forest fires through their localization. There is a known method for limiting the spread of forest fires, including the creation of fire barriers in all the forests of the forest by spraying non-burning materials perpendicular to the direction of fire propagation. However, this method is characterized by insufficient efficiency in the fight against forest fires. The aim of the invention is to increase the efficiency of localization of highland fires. The goal is achieved by the fact that according to the method of limiting the spread of forest fires, including the creation of fire barriers in all the forests of the forest by spraying non-burning materials perpendicular to the direction of fire spread, non-burning materials use materials that solidify in air at P "1 ± 5% ATA and (15 ± 5) T 4 50 ° C, to increase the surface of the forest canopy, where P is the pressure. T is the temperature. A prerequisite for the spread of forest fires is the presence of a sufficiently strong wind in the forest canopy. Therefore, an artificial decrease in wind speed in all the rivers of the forest, incl. and in its canopy, leads to a decrease in the rate of spread of highland forest fires and to its cessation. The presence or absence of a strong wind in the forest region is largely determined by the aero dynamic properties of the forest. In denser (non-windable) forests, the crowns are less crowded and it would seem that in such forests there should be a rare occurrence of forest fires. However, in denser forests there is a large supply of sand-burning materials, which leads to an intensification of burning. Therefore, in order to effectively limit the spread of upper fires, it is necessary to significantly reduce the blowing through of the forest canopy without increasing the supply of combustible materials. This is achieved using the proposed method. Fiberglass fabrics, flexible fire-resistant polyurethane foams, materials based on urea and phenol-formaldehyde resins can be used as materials that reduce the flow rate of crowns and are non-fusible. In addition to this, fire shields created in this way are a means of reducing radiant and convective heat fluxes from a fire front approaching the barrier to unburned forest, because the increased free path of radiation is reduced due to the increased effective density of the forest. The materials used to create fire barriers should satisfy the following requirements. Since fires occur only in spring, summer, and autumn, these materials should harden under the same thermodynamic conditions, namely, at a pressure of P 1 ± 5% at, temperature (15 ± 5) С T i 50 ° С. In addition, the solidification time of the material should be no more than 1 hour, which is dictated by the need to localize the fires in an extremely short time. An example of calculating the required width of the artificial anti-protective barrier and the required amount of material. When used as materials that reduce the flow rate of crowns hardened in air, an artificial fire barrier is created by spraying these materials in all the forests of the forest. These materials, hardened, long thin threads, which significantly increase the specific surface of the vegetation. The rate of Betpa falling in the forest canopy can be estimated in the following way. Let there be a forest with a known value of 5 and a drag coefficient of Cd. In the direction of the spread of fire create a fire barrier. In this case, the specific surface area of the screen is 53 5 + 5, and the aerodynamic drag coefficient Crf, where s, is the specific surface area of the material used to create the screen. The wind speed distribution in the forest canopy is described by the equation for the conservation of momentum dU p. with and -k-y. where a / is the friction stress value at the upper boundary of the forest canopy. From (1) it follows that, -2С., CdS (). An analysis of formula (2) shows that the larger the value in relation to the value, the stronger the wind speed drops in the created barrier. The value varies little for different types of forests. Therefore, we can assume that C j c; Ccit. Then from (1) it follows that in order to reduce the wind speed in the forest canopy by K times compared with the wind speed in the incident flow, it is necessary to at least increase the specific surface of the forest canopy. Let, for example, it is necessary to reduce the wind speed in the canopy by 1.5 times, i.e. , 5, then when creating a fire barrier / it is necessary to increase the specific surface S of vegetation not less than 2.25 times. From the formula (2), meaning that the wind speed is equilibrium to the barrier ui t ,, you can determine the width of the barrier I Cd, 2Cd75; 7 Let Col, 53 4CdS. x # eColS (4 / 2,2S-1) Cd5 Having in mind that .dl of pine forests CeJ 0.03, m, we obtain the width of the fire protection barrier. Now it is necessary to calculate how much material hardens in air per unit volume of the forest canopy is required. Since in solidified state such a material is a long filament, the mass from: a single filament is N (, where I is the radius of the filament; L is its length; j) the density of the material. Let M be the mass of material per unit volume. Then the number of threads per volume unit .. -MM. yTgChr the surface of the thread of the thread S. 2Jrr (r + L | 2Jfr-L ak as r. L. The total specific surface of the uty. 5, I, E, J as we want Since to increase the specific surface of the barrier 5 ef 4 times, then m Then M g 5/2. The radius of the filaments is 0.5-10 m, p 500 kg / m. Therefore, M is 0.36 kg / m. To determine the efficiency of the method, semi-natural experiments were performed. Example: To test the effect of artificial barriers The following experiments were carried out in all the forests of the forest from non-burning materials hardening in the air. 2–3 m create 3 lanes parallel to each other. The width of each strip is about 3 m, length - 20 m, tree arrangement density of 3 pieces per 1 m. On the windward side of the forest belts they create an ignition zone, which is a pile of drying with dimensions: length 3 m, width 1 m, height 0.5-0.7 m, packing density 0.2-0.3. The size of the ignition zone is chosen for reasons of reliability of initiation, as well as minimal impact on the process of spreading fire. At a distance of 10 m from the beginning of the ignition zone, in order to substantially change the aerodynamic characteristics of the forest belts, the material hardening in air is sprayed with a knapsack sprayer. An aqueous solution of polyvinyl acetate is used as such material. The solution is sprayed on the crowns of trees and on the litter. The consumption of polyvinyl acetate is about 300 g / m forest. The width of the created barrier on the first lane is about 2 m, on the second lane - about 3 m. On the third forest belt the barrier is not created; it serves as a control one. After hardening that occurs 60 minutes after spraying, all three lanes simultaneously initiate a forest forest fire by burning the ignition zone. During the experiment, a steady wind had occurred, the speed of which was 3-4 m / s, and the direction coincided with direction of the forest belt. The speed of advance of the flame front to the barrier is in this case in kroons 0.07-0.09 m / s and in the litter 0.03-0.05 m / s. On all three lanes, the rate of advancement of a fire is the same to the screen. The total heat flux in crowns, trees in the fire front is 60-70 kW / m. When the front of the fire approached the fire, the speed of fire spread sharply fell on two lanes, on which artificial fire beds were created5, and on the lane where the barrier width was 3 m, the fire stopped altogether, and where the barrier is 2 m wide The fire went down, very weak and in this mode spread across the litter to the end of the strip. The control strip burned completely in the top fire mode. Thus, as a result of the experiment, the effective operation of artificial barriers created from non-insoluble materials hardening in air was established. In practice, the width of the barrier was less than calculated. This fact can be explained by the additional action of fire barriers created in this way on the reactive properties of forest combustible materials (FCM). Indeed, the pyrolysis temperature of polyvinyl acetate is 10-60 ° C higher than the LGM pyrolysis temperature. In view of this, the energy that is leached in the front of the fire is also expended on the decomposition of the barrier material. The proposed method of limiting the spread of forest fires can be used as a preventive and operational means of fighting forest fires. In this case, if the method is used as a preventive measure, the above fire barriers are created in advance when carrying out preventive fire interventions. In this case, the screens are arranged perpendicularly to the predominant wind direction, which is well known for each particular locality. In the case of operational use of the invention in the fight against an existing fire, an artificial fire barrier is created in front of the fire front perpendicular to the direction of its spread. Using the proposed method of limiting the spread of forest fires as compared with the existing ones makes it possible to limit the spread of the most dangerous forest fires, less laboriousness of the method, a decrease in the convective and radiant component of the fire front toward the unburned forest by 2-3 times, an increase in the pyrolysis temperature forest combustible materials at 10-60 C.

Claims (1)

METHOD FOR LIMITING THE FOREST FIRE DISTRIBUTION, including the creation of fire barriers in all levels of the forest by spraying incombustible materials perpendicular to the direction of fire propagation, characterized in that, with a chain to increase the efficiency of localization of top fires, materials curing in air at P = 1 are used as incombustible materials ± 5% ata and (15 ± 5) ®С ί Т ί50 ° С, to increase the specific surface of the forest canopy, where Pressure, Т - temperature. > 1 1134202