UA137115U - APPLICATION OF GUANIDINE POLYMERS FOR PREVENTIVE FIRE TREATMENT OF FOREST PLANTS - Google Patents

Abstract

The use of an aqueous solution of guanidine polymers, which simultaneously have the properties of polyelectrolyte and surfactant, as a fire-fighting mixture for preventive treatment of forest stands, at temperatures below 350 ° C to slow the burning rate at the initial stage, and at temperatures above 350 ° C to inhibit active flame centers in the reactions of the radical combustion mechanism.

Description

The useful model belongs to the use of fire-resistant fire-resistant aqueous mixtures for the preliminary treatment of forest combustible materials, localization and prevention of forest fires, the laying of preventive barrier fire protection strips, barrier strips immediately in front of the edge of the fire and support strips in forest areas.

Solutions of inorganic salts of ammonium phosphate and ammonium sulfate (1-2) are considered the most effective for preventing forest fires (US Patent 4971728).

The advantages of known mixtures are the ability to form an oxygen-impermeable film of polyphosphates on the surface of the combustible material. The components of such compositions, in addition to the properties of flame retardants, simultaneously exhibit the properties of mineral fertilizers ((МНа)2НРО).

However, known mixtures have low weather resistance, because after evaporation of water, the protective layer becomes loose and soluble substances are easily washed out of it under the influence of atmospheric precipitation.

Mixtures based on soluble calcium salts with chlorides, sulfates of other metals (US Patent 4950410) and on the basis of bischofot (51.

The advantages of known mixtures are their good solubility in water, the presence of mineral fertilizer components, ease of use, and at the time of preparation they are active flame retardants.

The main disadvantages of known mixtures based on soluble salts are high cost and low weather resistance.

For longer fire protection of forest combustible materials, insoluble compounds in the form of dispersions based on natural clay mineral (bentonite clay), phosphogypsum |6) are used (A. s. USSR 1077912, Patent VU 18478).

The advantages of these mixtures are the possibility of using technological waste of mineral fertilizers. The main disadvantages of known fire retardant mixtures based on dispersions are their poor adhesion to forest combustible materials, low stability and viscosity and, as a result, low fire retardant capacity, as well as the need for careful grinding during preparation, since during spraying it is possible to clog the holes of the sprayer.

There are known fire retardant mixtures used to protect forest areas from fires, including by aviation, based on polymer thickeners: copolymers of acrylic acid, polyethylene glycols, modified polyacrylamides, polyethylene ethers, polyethylene oxides, carboxymethyl cellulose, modified guar polysaccharides, polyoxyethylene sorbitol, monooleate, natural polysaccharides (9-10.

The advantages of such mixtures are an increase in the viscosity of the solution, a decrease in the amount of spray and losses from evaporation and wind erosion, which allows you to increase the length of the fire-resistant strip by obtaining a compact jet. The main disadvantages are insufficient economy.

Surface-active substances (surfactants) of various nature are used to increase the wetting ability of solutions and increase fire-retardant efficiency |2, 5, 9), (Patents VU 2149,

VU 1326).

The advantages of such mixtures are a decrease in surface tension, an increase in viscosity, and a decrease in the linear burning rate. The disadvantages are insufficient economy of use and low weather resistance.

A mixture is known for the prevention, localization of forest fires and/or fighting them (VU Patent 2149), which is a dispersion of ammonium phosphates of aluminum and zinc in a true solution of diammonium phosphate with the following composition of components: АИг2Оз: 7п0: Р2О5:51О2:МНз-1 ,0: 2.4: 17.3: 1.0: 3.9 is mass-produced in Belarus under the trade name "Metafossil" (base composition).

The advantages of this mixture are the reduction of ash output by 2-3 times during the combustion of treated wood, as well as the white color of the laid mineralized strip.

However, this mixture has the following disadvantages: high cost due to the use of zinc compounds for its synthesis, use of aggressive (aqueous ammonia solution, 62-65 95 solution of orthophosphate acid) raw materials, great bulkiness and toxicity of operations (sol-gel synthesis method), heating mixture at a temperature of 100-105"C under conditions of intensive mixing, poor adhesion to forest combustible materials, low stability and viscosity and, as a result, low flame retardant capacity.

As the closest analogue, the composition for obtaining a fire-retardant and fire-extinguishing composition for fighting forest or peat fires (VU Patent 1326) was chosen. The closest analogue requires the use of toxic substances (aluminum and zinc oxides, ammonium hydroxide, sodium hydroxide, lauryl sulfate or sodium alkyl sulfonate). Its main disadvantages are insufficient economy and complexity of synthesis operations. In addition, the storage period of the working (10 95) solution is only 30 days.

The basis of the useful model is the task of obtaining an economical, effective, long-term storage-resistant, environmentally safe water mixture for the preventive treatment of forest combustible materials, which can be mass-produced in Ukraine.

The task is solved by using an aqueous solution of a polymeric surfactant (surfactant) of the guanidine series for the preventive treatment of forest combustible materials. At a burning temperature of less than 350 "C, guanidine polymers are used to slow down the burning rate. At a temperature of more than 350 "C, guanidine polymers are used to inhibit active flame centers in the reactions of the radical combustion mechanism.

In fire-fighting mixtures, polyhexamethyleneguanidine (PGMG) is used in the form of its soluble salt form: bno

MN. x p (where X is NSI or NgRO", p-30-90) polyhexamethyleneguanidine phosphate (PGMGF) under the trade name "Gembar" or polyhexamethyleneguanidine hydrochloride (PGMG-HC) under the trade name "Aquaton" or polyhexamethyleneguanidine urea phosphate under the trade name FSH -1, which can additionally contain urea, orthophosphate acid and water in the following ratio of components, wt. 9o: polyhexamethyleneguanidine 0.01-35 phosphate (hydrochloride) urea 3-50 orthophosphate acid 5-10 water the rest.

PHMG salts are high-molecular derivatives of a specific nitrogen-containing compound - guanidine, which belongs to the class of strong polybases and is a polyelectrolyte containing ionogenic guanidine and hexamethylene groups, which determine the ability to adsorb at the boundary of the phase distribution together with a decrease in the surface tension of water (|13-141| .

In the temperature range of 25-350 "С, PGMG is a heat-resistant polymer (14-15), which slows down the rate of burning at the initial stage, and above 350 "С, PGMG decomposes on the combustible surface with the formation of a large number of nitrogen-containing ((МНа», МН», МН ", МН, МО", МОг", МОз")) ions which, entering into the reaction of the radical combustion mechanism, inhibit the active centers of the flame 15). For phosphorus-containing guanidine compounds, the presence of ions (НеРОг, НРОг, РОз, РО», РО , Ryu",

Pg2Oz) increases the effectiveness of both homogeneous and heterogeneous inhibition of combustion chain reactions (151.

In addition, PGMG salts are environmentally safe substances and are widely used. in medicine as antiseptic, antibacterial and therapeutic agents (Patent NO228732502, VI 264846902, MO pIg241102802), belong to the IM toxicity class (13), which allows solving the environmental problem and abandoning harmful substances that were used earlier.

The causal relationship between the features that make up the essence of a useful model and the technical result that is achieved is explained as follows.

Forest combustible materials are a polymer of vegetable origin, consisting of a mixture of natural polymers: cellulose, lignin, hemicellulose (16)Y. On average, coniferous wood contains 48-56 95 cellulose, 26-30 90 lignin, 23-26 95 hemicellulose (|15). Since the surface of forest combustible materials is built of anion-active macromolecules and has a negative charge, materials that have a positive charge are related to such a surface, i.e. cationic-active macromolecules, namely PGMG salts, which simultaneously exhibit the properties of a cationic surfactant and a quaternary ammonium salt. The PGMG polymer film has high adhesion to anionically charged materials, that is, to forest (cellulose-containing) combustible materials (13).

Guanidine polymers quite easily enter into chemical reactions with cellulose-containing materials with the formation of mesh interpolymer complexes and covalently bonded interpolymers, which after drying form water-resistant polymer films on the surface with high strength characteristics and a prolonged biocidal effect (13), which is due to the presence in the composition PGMG of guanidine groups, which are combined into a common polymer chain, but only a part of them always participates in the chemical interaction, and free groups give the substance biocidal properties, which is especially relevant for preventive measures aimed at protecting forest plantations from pests.

Modification of the proposed composition on the surface of forest combustible materials was carried out by spraying PGMG salts on the surface of forest combustible materials.

In addition to the barrier function of accumulation of radionuclides, coniferous forest plantations become intensely dry in the spring-summer period, and essential oils, resin and rosin, under the influence of temperatures above 40 "C, soften and appear as transparent droplets on the surface of the wood.

Under the influence of light in the air, they quickly oxidize and stand out from the wood, turning into hard drop-shaped balls with a glassy structure. When they are exposed to the light rays of the sun at a temperature above 40 "C, these solidified transparent vitreous balls of essential oils, rosin and resin, released from the tree onto its surface in the form of drops, due to the vitreous structure and transparency, perform the function of "optical lenses". the light beam of the sun, in which it is concentrated into a point source of energy, which can lead to the spontaneous ignition of the tops of dry pine trees, resin, etc. I17|Й. The use of a method of treating the surface of coniferous plantations by spraying PGMG salts reduces the number of resinous formations, which is confirmed by IR spectroscopy.

The impact of atmospheric precipitation on the polymer film of the fire-resistant composition contributes to its gradual hydrolysis and dissolution, with the formation of nitrogen- and phosphorus-containing mineral compounds that contribute to the accelerated growth of vegetation, which becomes a natural obstacle to the advance of the fire front in the event of a fire.

Composition for the preventive treatment of forest combustible materials, which is claimed to be obtained by dissolving the reagents "Aquaton", "Gembar" or "FSH-1" in water in a ratio of 1:1; 1:2, 1:3; 1:4 until a homogeneous solution is obtained.

Below are examples of formulations of the claimed composition and the results of laboratory studies of their flame retardant properties.

Example 1. The "Aquaton" reagent is dissolved in water in a ratio of 1:11 until a homogeneous solution is obtained.

Example 2. "Gembar" reagent is dissolved in water in a ratio of 1:11 until a homogeneous solution is obtained.

Example 3.

FSH-1 is dissolved in water in a ratio of 1:2 until a homogeneous solution is obtained.

Example 4. FSH-1 is dissolved in water in a ratio of 1:3 until a homogeneous solution is obtained

Example 5. FSH-1 is dissolved in water in a ratio of 1:4 until a homogeneous solution is obtained

The table shows the results of laboratory tests in accordance with examples 1-5 on indicators of fire protection efficiency in relation to forest combustible materials.

The fire-resistant efficiency was determined according to the following criteria: loss of mass of a fire-resistant sample of forest combustible material (the first group of fire-resistant efficiency includes mixtures whose treatment leads to a loss of mass of forest combustible materials after fire tests of no more than 9 95, to the second group - if the loss of mass is from 9 up to 25 95); linear speed of flame propagation (this is the speed of flame propagation along the surface of the combustible material, i.e., the distance traveled by the combustion front per unit of time (m/min);

According to the data in the table, the flame retardant properties obtained by the claimed composition, as well as by the closest analogue, belong to the 1st group of flame retardant efficiency.

Table 1

Chemical composition, flame retardant efficiency in relation to forest combustible materials

Mo recipes Loss Group Linear speed | The fire protection efficiency of the composition by mass is 9, | Flame retardant distribution on the surface of forest fuels as an example of flame efficiency, m/min materials, g/m?

Analog | 86 | (HER 77777177 л180-2г00С1С 7772. 89 | щющющь11 | 0334 | щ-Б with Ж шеле 1 | le sample

The essence of the useful model is explained by the graph (Fig. 1), which shows a decrease in the mass loss of treated wood samples to 7.7 956 under the conditions of consumption of the FSH-1 reagent of 350 g/mu. Therefore, it is most appropriate to use the composition according to example 3 and 4, which has advantages over the known analogue (Patent VU 1326). The linear burning rate of wood treated with the composition according to example C (FSG 1:2) decreases by approximately 4 times compared to untreated samples, and a noticeable attenuation and reduction in mass loss of treated (sprayed) samples of forest combustible materials is visually observed (Fig. 2).

Tests of the fire-extinguishing efficiency of forest combustible materials treated (sprayed) with the proposed fire-extinguishing mixture showed an increase in the strength of charred particles of forest combustible materials (due to the formation of polymer films on the surface at the initial stage of combustion), which prevents the removal and atmospheric spread of radioactive nuclides as a result of forest fires in the territories , polluted as a result

Chernobyl disaster.

Thus, the proposed mixture, when used for the purpose of forest fire prevention and containment, is significantly more stable during long-term storage, more effective and cheaper than known analogues, ecologically safe, promotes the growth of forest plantations, neutralization of pests, prevention of the spread of radioactive particles and dust suppression, which is especially relevant to reduce dose loads in conditions of radioactive contamination.

Sources of information: 1. Tne eyesi oi (MNOgNRO» apa (MNa)g65045 op She v5ropiapeoiv idpiyop rgorepie5 oi Ripiv

NaIerepzviv ripe peedaiez / 5. Podakiz Gei a.) // Rige zaieiu |oshtpai!.-2002. - M. 37. - R. 481-494. 2. Artsbashev E.S. etc. Development of a fire-extinguishing composition based on phosphorous-ammonium salts. / E.S. Artsybashev and others // Forest fire and fight against them: Sat.

Lennyilkh / Ed. E.S. Artsibasheva. - L.: Lennyylki, 1989. - P.61-69. 3. US patent 4971728, IPC C 09K 021/00; C 090 005/16; C 090 005/18; A 620 001/00, 1990. 4. US patent 4950410, IPC A 620 001/00; A 62C 001/00; A 62C, 1990. 5. Lorberbaum V.G. OSB-1 fire protection composition for combat! with forest fires / V.G.

Lorberbaum, I.N. Sedyna // Forest fire and fight against them: Sat. science tr Pod. ed. E.S.

Artsibasheva. - L.: Lenniylkh, 1986. - P. 96-102.

Zo 6. Artsybashev E. S. Development of fire-extinguishing compounds based on natural sulfur and technological waste mineral fertilizers / Artsybashev E. S., Gur'ilev S. M., Pyrogova

T. G. / Fight against forest fires: workers of S-PONYLH / Ed. E. S. Artsybasheva. - S-Pb., 1998. - P.60-68. 7. Author's certificate of the USSR 1077912, IPC C 09K 3/28, 1984. 8. VU patent 18478. Composition for obtaining a fire-protective and fire-extinguishing composition for fighting forest or peat fires, IPC A 620 1/00, C 1, 2013. 9. Smirnov A.P. Forest pyrology: Study guide / A. P. Smirnov, E. S. Melnikov//SPo:

SPBGHLTA-2006.-60. 10. Moiseenko M.V. Influence of additives of high-molecular compounds on the fire-extinguishing and fire-protective properties of water M.V. Moiseyenko, P.F. Dubkov // Theoretical and experimental fire extinguishing: Sb.nauch.tr - M.: VNIYPO, 1982.-p. 106-113. 11. Patent VM 2149. Composition for prevention, localization of forest fires and/or fighting them. IPC A 620 1/00, C 09K 21/02, 1998. 12. Patent VU 1326. Composition for the preparation of a fire-retardant composition for preventive treatment of forest combustible materials and prevention of forest fires, IPC

A 620 1/00, C 1 06/30, 2010. 13. Hembytsky P. O. Polymeric biocidal preparation polyhexamethyleneguanidine / P. 0.

Gembytsky, I. I. Vointseva// - Zaporozhye "Polygraph", 1998.-44sb. 14. Maglevana T.V. Ecological aspects of the use of guanidine polymers in emergency situations: |Monograph| Second edition/ T. V. Maglyovana, T. Yu. Nyzhnyk, S. V.

Zhartovsky - Cherkasy: publisher of FOP Gordienko E.I., 2017-210 p. 15. Semi-empirical method of calculating a number of physical and chemical parameters / D.S. Kaganyuk,

V.M. Zhartovsky // Monograph. - K.: IPC "Kyiv University", 2006.-273S. 16. Bobkov S. A. Physico-chemical foundations of development and fire extinguishing: учеб. allowance / S.

A. Bobkov, A. V. Baburin, P. V. Komrakov //- M.: Academy of State Educational and Scientific Research of the Ministry of Emergencies of Russia, 2014.-210 p. 17. Demidov P.G. Burns and properties of combustible substances: textbook. manual - 2nd ed., revised. /

P.G. Demidov, V.A. Shandsba, PP. Shcheglov //- M.:, 1981-272 p. 18. Patent VO 228732502. Disinfectant "teflex" 19. Patent VO 264846902. Medicinal coating layer.

20. MONA patent 241102802. Compositions for the care of the oral cavity, containing a cationic active component!.

Claims (2)

USEFUL MODEL FORMULA 1. The use of an aqueous solution of guanidine polymers, which simultaneously have the properties of a polyelectrolyte and a surface-active substance, as a fire-fighting mixture for the preventive treatment of forest plantations 2. Application according to claim 1, which is characterized by the fact that guanidine polymers are used at a temperature of less than 350 "C to slow down the burning rate at the initial stage. C. The application according to claim 1, which differs in that guanidine polymers are used at a temperature of more than 350 "С to inhibit the active centers of the flame in the reactions of the radical combustion mechanism. : WHAT : u u : U : y how s ha : ! : : zhk u i I | Iv n zhom u dm se do 5 U Mo le Fig. 1 o. with . with Fig. 2,000 Computer keyboardG. Payalnikovo 00000000 7 Ministry of Economic Development, Trade and Agriculture of Ukraine, (000000, St. M. Hrushevskyi, 12/2, Kyiv, 01008, Ukraine SE "Ukrainian Institute of Intellectual Property", str. Glazunova, 1, Kyiv - 42, 01601 b