GR1010408B - Materials, method and system for fire prevention and extinguishing - Google Patents

Abstract

The present invention relates to a non-toxic fire extinguishing hydraulic mortar and its suspension, to a fire extinguishing, fire prevention and fire protection method as well as to a system for applying said method. The mortar and suspension of the present invention exhibit secondary characteristics such as soil improvement on burned surfaces. The fire-fighting mortar consists of at least three cement clinkers in a ratio of 2:8 to 9:1 of the first material to the sum of the second and third material at least, and is used in the preparation of the suspension with water in a ratio of 1:9 to 3:7. The suspension is homogenized by stirring and is sprayed immediately and directly onto a burning surface or onto a surface to prevent fire by forming a mantle on this surface. After the evaporation of the water from the suspension, the surface cools so that the mantle creates a loose cement-like mass which acts as thermal insulator and asphyxiant, while trapping combustion gases and ashes.

Description

Materials, method and system of fire extinguishing, prevention and protection from fire.

DESCRIPTION

Technical Level: Fires of all kinds are a significant risk for the loss of human life, the destruction of property and agro-forestry areas, and the burden on the environment through the destruction of forests, and the contamination of the air, the water table by the products of combustion and also fire fighting materials, etc. For this reason, all organized societies have tried to get involved in an effective way in extinguishing all kinds of fires, but also in their prevention.

It is known today that three elements are necessary to start and maintain a fire: fuel, oxygen and heat. Since ancient times, the common means of fire extinguishing is the use of water to lower the temperature of the burning or protected surface with the aim of extinguishing the fire and preventing ignition, respectively. The water being in liquid form does not accumulate and therefore whatever quantity does not evaporate during throwing and reaches the burning surface flows from the surface minimizing the contact time of the water with the surface. This results in only a small percentage of the water being thrown actually contributing to the cooling of the burning surface. Also, the water is thrown under pressure with the result that it dissolves the cohesion of the burning surface and creates additional embers which can spread the fire to any surface they land on.

Other common firefighting techniques are covering the burning or protected surface with material that limits or completely cuts off the contact of atmospheric oxygen with the burning or protected surface to cause suffocation and extinguish the fire or prevent the surface from burning. An example of such techniques is the throwing of soil, clothes, etc. with limited results on fires that are beyond the first stages of their occurrence.

In the last two centuries, the organization of fire services with the aim of extinguishing and preventing all types of fires has led to the development of a multitude of fire extinguishing materials and methods, adapted to the type of fire to be dealt with (e.g. solid, liquid, presence of electricity, etc. ). At the same time, these developments led to the development of fire fighting and fire protection systems, such as fire pumps and hoses, portable fire extinguishers, automatic fire extinguishing systems, fire trucks, aerial fire fighting means, etc.

In most fires, the primary mode of firefighting and prevention is still water wetting, with the aim of cooling. This option is preferable as water is, in general, cheap and easily accessible, while it does not cause contamination, being a natural product.

In many cases, chemical additives can improve the fire-fighting performance of water, with the disadvantage of environmental contamination depending on the type of additives. Such admixtures are, for example, inert materials, synthetics, microplastics, etc. materials which usually expand as they burn and produce residues with thermal insulation etc. properties. At the same time, the use of such admixtures can be prohibitive for large-scale fires, such as forest fires, since, in addition to the possible contamination of the environment, they have a significantly higher cost than water.

The use of water for firefighting also has the disadvantage that as it is thrown from a distance due to the very high thermal radiation emitted by the fire, much of the water evaporates before it has time to settle on the burning surface and cool it, while outdoors a significant amount of the spray is carried away by the wind, especially in forest fires, in which, in addition, the aiming of the spray cannot be done with sufficient accuracy, with the result that a significant amount of water is lost without significant results.

At the same time, embers (i.e. burning solid derivatives of combustion) produced on the burning surface are carried away by the superheated combustion gases and transported to a great height, where with the help of the wind they are carried away and deposited on unburned surfaces, thus contributing to the faster spread of the fire. In these cases the use of water is not effective.

In other cases, an attempt is made to thermally insulate the burning surface and isolate it from atmospheric oxygen, thus depriving it of two main factors of fire maintenance and spread, i.e. heat and oxygen. This goal can be achieved by using fire extinguishing foam or powder. In the first case the foam has as a component water and another foaming component, while in the second the powder has fluid properties in a gas under pressure. At the same time, the powder has the disadvantage that it does not stick to the surface it is thrown on, but simply settles, with the result that a significant part of it is carried away from the burning surface. These methods can offer satisfactory fire extinguishing and fire prevention results but have a high cost and as they include chemical components they often have a significant environmental footprint and can cause respiratory etc. health problems for those who inhale it during or after extinguishing as foam and dust can remain on surfaces for a long time after the fire is extinguished. They are also not suitable for agroforestry fires.

Despite the advantages offered by fire extinguishing foam and dust, their outdoor disposal (especially for dust) can be significantly affected if there are winds, as a significant part of it can be carried away and not end up on the burning surface, but also be carried away after their deposition on the burning surface drastically reducing the fire extinguishing and suffocating effect.

Foam and especially fire extinguishing powder can, therefore, only under conditions and only partially create a mantle around the burning surface in order to lower the temperature and cause suffocation. This is a major drawback which reduces their effectiveness.

Problem Definition: It is therefore clear that a firefighting material, method and system are required which with improved firefighting and deterrent ability solve the problems and limitations faced today in firefighting and fire protection in indoor and outdoor fires.

More specifically, a fire-fighting material, method and system is required which show higher fire-fighting and fire-prevention efficiency while being friendly to the environment and people, easily accessible and at a cost equal to or lower than known materials.

Suggested solution:

Fire Fighting Hydraulic Mortar

The present invention concerns fire-fighting hydraulic mortar which consists of three categories of components, the A, B and C category of components. The ratio of A to the sum of B and C class ingredients in the mortar ranges from about 2:8 by weight (wt) to 9:1 w/w. The preferred ratio is 7:3 wt.

Table 1 shows the members of the A, B and C component classes. Class A ingredients include calcium compounds and magnesium compounds such as Calcium Hydroxide (Ca(OH)2), Calcium Oxide (CaO), Magnesium Hydroxide (Mg(OH)2), Calcium Carbonate (CaCO3) and Magnesium Carbonate (MgCO3 ). The B category of ingredients includes salts such as Potassium Oxide (K2O) and Sodium Oxide (Na2O). The C category of components includes ferrous compounds, such as Iron (III) Oxide - (Fe2O3) or other iron oxides) and aluminosilicate compounds, such as Silicon Dioxide - (SiO2) and Aluminum Oxide - (Al2O2)).

Table 1: Members of the A, B and C class of components

The materials of the A, B and C category of components give the mortar the properties they possess individually but also combined properties after they are mixed with water and the water evaporates, when they crystallize.

Table 2 shows the range of proportions in the mortar for each of the members of the A, B and C class of ingredients, as well as three examples of mortar according to the present invention.

The selection from the ratio range for each material is made so that the sum of the percentages of the A, B and C category of ingredients is 100% and at the same time the sum of the percentages of the A category of ingredients to the sum of the percentages of the B and C category of ingredients is ranges from about 2:8 wt. to about 9:1 wt.

Example (Ex.) 2 shows a mortar in which the sum of the percentages of all components of component class A to the sum of the percentages of all components of component class B and C is about 9:1. Example 3 shows a mortar in which the sum of the percentages of all components of component class A to the sum of the percentages of all components of component class B and C is about 2:8. Example 1 shows a preferred mortar in which the sum of the percentages of all components of the A component class to the sum of the percentages of all components of the B and C component classes is about 7:3. The preferred mortar of Example 1 exhibits the best combination of fire-extinguishing-fire-protective characteristics, agglomeration, surface adhesion and soil improvement over all possible combinations of ingredients while also achieving the best result.

Table 2: Range of proportions in the mortar for each of the members of the A, B and C class of ingredients, as well as three examples of mortar according to the present invention.

Table 3 contains the individual and combined properties of the members of the A, B and C class of mortar components. The ingredients of the C category of ingredients help the structural stability of the resulting product when they are diluted with water. Thus they facilitate the creation of a mantle firmly attached to the burning surface or to the surface to be protected from fire. The materials of the magnesium category are friendly to the environment and people.

Class A ingredients all exhibit high adhesiveness when mixed with water. By evaporation of water either from the heat of the fire or from the atmospheric temperature, the components of category A form a loose mantle on the surface on which they are deposited, which can be easily removed with water or mechanically. At the same time, the components of the A category have a high adhesion to the burning surface, so they are suitable for coating the burning surface with the aim of insulating it (after it has been cooled with water first) in order to avoid its reheating by flames from neighboring burning surfaces that would cause re-ignition of the surface. The high adhesion and nature of the mantle also ensures the isolation of the burning surface from atmospheric oxygen to create suffocating conditions on the burning surface and more effectively extinguish the fire in the absence of oxygen.

The magnesium class of ingredients in the A class of ingredients provides magnesium to plants around burning plants in agroforestry fires. Magnesium is a necessary component for plants to form chlorophyll, a substance necessary for the process of photosynthesis, which in turn is necessary for the survival and growth of plants. Therefore, the magnesium class of ingredients of the A class of ingredients can be used to support the growth of plants around burnt agroforestry areas, which plants have been shocked by the thermal radiation produced during the fire and by the combustion derivatives . In other words, magnesium class materials are friendly to the environment and people.

Corresponding to the use of the magnesium class of components of the A category to support the growth of plants, all the components of the A and the salts of the B category of components have a corresponding effect, which correct the pH of the soil which is affected by acid rain or which, among other things, is created by the gaseous pollutants of the fire.

The salts of the B class of ingredients also have a positive effect on the growth of plants, which act as a soil improver, offering favorable conditions for their growth. In other words, B category salts are friendly to the environment and people.

All the ingredients of all three categories help to correct the pH of the soil which is disturbed by acid rain, while at the same time they are fire resistant and therefore suitable for use at the high temperatures that develop in the various types of fires without deteriorating and practically without swelling or burn, offering thermal insulation. In other words, all the ingredients of all three categories are friendly to the environment and people.

In addition to the individual properties of the components of the A, B and C category of components, the combination of these components enhances the effectiveness of the mortar for fire extinguishing by thermally insulating the burning surface (after cooling it with the water used to dilute the mortar) or for surface fire protection, as well as to create suffocation conditions by isolating atmospheric oxygen from the burning surface when the stable refractory mantle is created around the surface.

Finally, the combination of the components of the A, B and C group of components also improves the soil improvement properties of the mortar and therefore makes the mortar particularly suitable for agroforestry fires. In other words, the combination is friendly to the environment and people.

Table 3: Individual and combined properties of the members of the A, B and C group of mortar components.

To improve fire extinguishing and fire protection, the firefighting hydraulic mortar must include at least one component from the A component group, at least one component from the B component group, and at least one component from the C component group. All components must be in powder form with a diameter equal to or less than 100 microns to facilitate the dissolution of the hydraulic mortar in water and the creation of a mantle on the burning or fire-protected surface with sufficient adhesion to provide both thermal insulation for firefighting and isolating the surface from atmospheric oxygen for surface and fire suffocation.

It is pointed out that the fire-fighting hydraulic mortar contains non-toxic and environmentally friendly, plant- and human-friendly ingredients, each of which is widely distributed and available on the market, at a cost lower than the chemical ingredients used in all known fire extinguishers and fire protection materials, except without water additives and additives.

Fire Extinguisher Suspension

Diluting the hydraulic mortar of the present invention in water results in a fire-fighting suspension. For the preparation of the suspension, it is necessary to dilute the mortar in water with a ratio of 1:9 to 3:7 so that the suspension has the desired fire extinguishing and fire protection characteristics, mainly that is, the creation of a stable mantle attached to the burning or the surface to be fire protected, suitable for removal by water or mechanical means without causing damage to the surface.

The fire-extinguishing suspension depending on its content of fire-extinguishing powder is in the form of water with suspended dust or in the form of fine-flowing mud and is suitable for pumping and use in a fire hose supplied with the suspension under pressure.

The suspension must be homogenized before use, for example by mechanical stirring or other agitation method, to ensure that it retains its properties and to facilitate disposal using conventional fire extinguishing systems.

If the suspension has to be stored before its disposal, then depending on the storage time it loses its homogeneity. In this case, the continuous stirring of the suspension ensures that it is always homogenized so that it is more effective for fire extinguishing, prevention and fire protection.

For the preparation of the mortar, moisture is optionally removed from the mortar components (e.g. by heating or another method known in the relevant literature). Preferably, the final moisture content of the ingredients used in the mortar and of the mortar itself is about 0%. To keep the mortar in a dehydrated form until use, the mortar can be packed and sealed in a watertight-airtight package.

To facilitate the dissolution of the mortar in water and the creation of a homogeneous suspension, it is preferable to unseal the mortar from its package when it is to be dissolved in water. In this way, the absorption of moisture by the mortar is avoided and therefore the mortar agglomerates before it is added to the water. This facilitates both the dilution of the suspension in the water to be used for fire extinguishing or fire prevention and protection, as well as the homogenization of the suspension so that it maintains its characteristics to the maximum extent after it has been thrown.

Fire Extinguishing Method Using Fire Extinguishing Suspension

The fire extinguishing suspension can be used both for extinguishing fire and for prevention, either to create a protective mantle on objects and surfaces, or to cover soil and vegetation with the aim of creating fire-resistant zones in agro-olive areas.

In a first embodiment of the method, the suspension is prepared according to what was described above. More specifically, the mortar is added together with water in a ratio of 1:9 to 3:7 in a barrel equipped with a stirrer and stirred until a homogeneous suspension is created. The homogenized suspension is pumped into a fire truck tank in which a mechanical stirrer has been installed which continuously stirs the suspension so that it does not lose its homogeneity until it is used for fire fighting or fire protection.

The preferred mechanical agitator for the slurry preparation drum and fire truck tank is a rotary agitator transversely mounted on vertical sides of the drum and tank.

In an alternative embodiment, other types of mechanical or non-agitators may be used, as will be apparent to those skilled in the art.

The use of a stirrer in the barrel and one in the tank of the fire engine are sufficient to achieve the preparation of the suspension and to maintain its homogeneity. However, it is possible to use more stirrers.

In an alternative embodiment, the homogenized suspension is fed to a fire truck which does not have an agitator installed in its tank. In this case, the suspension is used immediately so that it does not lose its homogeneity.

When selected by the fire truck operator, the homogenized slurry is drawn from the vehicle's tank (or the vehicle's pump, bypassing the tank) and advanced under pressure to a hose operated by the operator to drop the slurry onto the selected surface for fire fighting or fire protection.

The operator continues dropping the slurry at least until the burning surface or the surface to be fire protected is completely covered by a mantle which is created when the water in the slurry evaporates under the influence of the fire temperature or the atmospheric temperature, respectively.

In the case of fire extinguishing, the temperature of the fire is much higher than the atmospheric temperature (it is of the order of hundreds of °C or even more than 1000 °C. This very high temperature causes sintering and transformation of the fire suspension, under the influence of thermal energy of the burning surface, in a cement-like mass of loose consistency (cement slag - clinker). The clinker creates a mantle, as mentioned above, which, after the evaporation of the water from the suspension has cooled the burning surface, thermally insulates the burning surface and it does not allow it to be reheated by thermal radiation coming from adjacent burning surfaces, thereby extinguishing the burning surface.At the same time, the mantle that now covers the surface does not allow atmospheric oxygen to come into contact with the surface and thus by suffocation it removes the second necessary agent for the maintenance of fire. As a result, extinguishment of the burning surface is achieved within a short time (typically within seconds).

At the same time, the mantle covering the burning surface traps the gases, soot (i.e. solid burning products of combustion) and ash (i.e. solid non-burning products of combustion) produced by combustion. Thus, the mantle ensures, respectively, fire extinguishing and protection of firefighters, etc. people from inhaling harmful gases, prevents fire from spreading to neighboring areas from airborne embers, and prevents ash from contaminating the atmosphere and water table.

In the case of fire protection, the same method is followed to cover the surface to be fire protected, only here the evaporation of the water from the suspension takes place by evaporation through the atmospheric temperature. As there is no supply of thermal radiation which could increase the temperature of the suspension to high temperatures (corresponding to the temperatures developed during a fire) no sintering is observed but simple agglomeration and transformation of the fire suspension into a cement-like mass of loose consistency.

The clinker mantle formed in both of the above cases can be removed at any time by simply using water or mechanically without requiring significant mechanical stress on the mantle as it consists of a cement-like mass of loose consistency which easily loses its cohesion. This loose consistency makes the cementitious mass easily destructible by simple wetting or splashing water (e.g. rain) or mechanically (e.g. mechanical stress from wind blowing bending tree branches or grasses on which they are coated with the cementitious mass).

The suspension is stirred continuously until it is poured.

In a second embodiment of the method the suspension is produced in a barrel and then pumped into a tank of aerial fire extinguishing medium where it is optionally stirred continuously until it is poured. Stirring is optional in the event that the casting is done immediately or shortly after the production of the suspension, as long as it maintains its homogeneity.

In a third embodiment of the method, the suspension is produced directly in the fire truck where it is homogenized and stirred continuously until it is dumped.

In a fourth embodiment of the method, the suspension is produced directly in the aerial fire extinguishing medium where it is homogenized and stirred continuously until it is poured.

Fire extinguishing system

Figure.1 shows an innovative fire extinguishing system. The innovative fire extinguishing system (100) consists of a fire engine (110) which is equipped with a water tank (120), a pump (130) connected to an outlet (121) of the water tank (120) and a hose (140).

With the inlet (122) of the tank (120) through a pipe (160) is connected a barrel (150) which is used for the preparation of a homogenized fire extinguishing suspension and which has inside the barrel a stirrer (155) which is preferably placed transversely in vertical barrel walls (150). The agitator (155) agitates the fire-extinguishing mortar and water in the barrel (!50) to produce a homogeneous fire-extinguishing suspension according to the method of producing a homogeneous fire-extinguishing suspension described above.

After pouring the homogenized fire-fighting mortar into the water tank (120) of the fire-fighting vehicle (110), the mortar must be poured onto the burning surface as soon as possible and in any case before the mixture loses its homogeneity and the mortar components settle to the bottom of the water tank (120), as this would create serious problems in pumping and dumping the suspension, possible damage to the pump (130) and the hose (140), and above all to the fire extinguishing properties of the suspension. More specifically, the suspension, when it has lost its homogeneity, when thrown onto the burning surface would not have the same homogeneity and density resulting in ineffective coverage and adhesion to the burning surface, unsatisfactory sintering, unsatisfactory cooling, thermal insulation and suffocation of the burning surface, and finally unsatisfactory ability to extinguish the burning surface and protect it from re-ignition, e.g. after its reheating by the thermal radiation of adjacent burning surfaces.

As it is not always possible to immediately throw (all) of the homogenized fire extinguishing suspension after it has been poured into the water tank (120) of the fire fighting vehicle (110), in an alternative, preferred embodiment of the fire extinguishing system (100), the water tank ( 120) is equipped with a stirrer (125) for the continuous stirring of the homogenized fire extinguishing suspension. The agitator (125) is optional but its use is recommended as this way the fire truck (110) can at all times be loaded with the homogenized fire extinguishing suspension and therefore be ready for effective fire fighting at all times, even when not it is possible to pour into it homogenized fire extinguishing suspension from a barrel (150).

The connection of the tank (150) with the fire engine (110) is made e.g. with a pipe (153) which, under the action of a transfer pump, transfers the homogenized fire extinguishing suspension from the barrel (150) to the tank (120). The transfusion pump can be located in the tank (150) or the fire engine (110). In the second case, either the pump (130) can be used, e.g. using suitable piping and valve for the option of decanting or dumping the homogenized fire extinguishing suspension, or a second pump. Transfusion pumps etc. are not shown in Figure 1 as they are obvious to those skilled in the art.

The tank (150) can be fixed, trailerable or self-propelled. In the case of a fixed barrel (150) the fire truck (110) is parked near the barrel (150) to transfer the homogenized fire extinguishing suspension. In the case of a towed or self-propelled tank (150), either the tank (150) can be parked near the firefighting vehicle (110), or vice versa, or a combination of the two, in order to facilitate the transfer of the homogenized fire extinguishing suspension before the homogenized fire extinguishing agent is dropped suspension for extinguishing the fire.

In an alternative embodiment of the system, the fire engine (110) may instead be an aerial fire engine, e.g. airplane or helicopter, which is equipped with a water tank (120). The pump (130) may optionally be installed in the aerial medium to fill (by transfusion) the water tank (120) with homogenized fire extinguishing slurry from the drum (150). In one aspect, the hose (140) is replaced by a port in the water tank (120) which opens to gravity drop the homogenized fire extinguishing slurry onto the burning surface.

In contrast to the known techniques of aerial fire extinguishing, the present system and the related extinguishing method, in addition to the above analyzed advantages, offer additional advantages. Among them, the entrapment of water by the hydraulic fire-fighting mortar within the fire-fighting suspension reduces the evaporation of water before the fire-fighting suspension settles on the burning surface resulting in more effective cooling of the burning surface. At the same time, as the aerial drops cannot be very accurate as due to the heat load developed by the fire and the smoke it emits, the drops must be made from a distance of tens of meters from the burning surface, the percentage of water that falls on the burning surface surface is only part of the whole of the throw resulting in insufficient cooling of the burning surface with all known aerial means of extinguishing fire. The percentage of the drop that ends up near the burning surface is essentially lost, as while it has a cooling effect on the surface that is not yet burning, that surface is heated by the burning surface and the water evaporates, resulting in only a slight retardation of fire spread.

With the proposed method, even the percentage of the throw that ends up close to the burning surface has a very important protective effect and prevents the spread of the fire. The reason lies in the fact that this rate of discharge of homogenized extinguishing suspension that lands on the unburned area initially cools it by evaporating the water of the suspension impinging on it and then thermally insulates it and creates a barrier that prevents atmospheric oxygen from coming into contact with the surface. Therefore, the spread of fire to unburnt surfaces is stopped.

The above action is so important that the aerial drops of the proposed hydraulic fire-fighting mortar can also be used to create fire zones in agro-forestry areas, etc., both as a means of prevention before the initial occurrence of a fire, and as an emergency solution to stop the fire spread of a fire after it starts. Corresponding use of all the implementation examples of the system (100) for creating fire zones can also be made by using a firefighting vehicle in the system (100) instead of an aerial vehicle.

In addition, the system (100) can either be installed in existing firefighting vehicles or aerial firefighting means (retrofitting) by installing agitators as described above, or by building firefighting vehicles, aircraft, helicopters, drones, etc. according to the above description of the system.

Based on the above examples of use, the fire extinguishing system (100) can also be used as a fire prevention and protection system both indoors and outdoors. Correspondingly, the fire extinguishing method described earlier can also be used as a fire prevention and protection method with the only difference being that due to the absence of the high heat load that develops in a fire, the evaporation of water from the fire suspension depends on the climatic conditions and the mortar in the homogenized firefighting slurry aggregates but does not sinter.

In an alternative embodiment of the system (100), instead of a firefighting vehicle (110) or an aerial vehicle, a portable device such as a portable fire extinguisher or other, as well as a fixed installation for dropping a homogenized fire extinguishing suspension can be used. The latter I could, e.g. to be used in the surrounding area of fuel storage tanks, factories, archaeological sites, etc. which are adjacent to agricultural lands and need immediate fire protection in the event of a fire spreading towards them.

The reason why such a fixed installation could be preferable is that the agglomerated (as well as the sintered) mass of the hydraulic fire extinguishing suspension after the evaporation of the water, turns into a cementitious mass of loose consistency with all the advantages mentioned above. This loose consistency makes the cementitious mass easily destructible by simple wetting or splashing water (e.g. rain) or mechanically (e.g. mechanical stress from wind blowing bending tree branches or grasses on which they are coated with the cementitious mass). While this degradation is desirable to avoid damage to the environment, it also means that a fire zone created with the present system has a finite lifespan which is a function of climatic conditions. So to avoid unnecessary repetition of the process of creating a fire zone around critical facilities, such as those mentioned above, the use of a fixed example of the implementation of the fire extinguishing/prevention and fire protection system can be more efficient and at the same time reduce the related costs.

Finally, as the sintered loose mass traps the ashes, the embers and the gases produced by the fire, the environment is protected, the fire does not spread and the firefighters etc. people are protected from inhaling harmful substances.

With the degradation of the mantle from the surfaces, its components are transferred to the soil and act as a pH regulator, soil improver and enhancer of chlorophyll production by plants. As a result, the regeneration of the burned area is facilitated and the growth of unburnt plants is also enhanced.

The examples used above to describe the present innovative solution should not be considered as limiting the scope of the present innovative solution. The present innovative solution can be applied in other scenarios and settings than those described in the examples presented above. The present innovative solution should be considered as applicable to any solid fuel gasification system of any type and purification of the produced gas.

The average person skilled in the art will understand that the shape, proportions and dimensions of the parts of the present invention, as shown in the exemplary embodiments, may be modified without departing from the scope and intended protection of the present invention. .

The above descriptions of exemplary embodiments are simplified and do not include parts that are used in the embodiment but are not part of the present invention, are not necessary to the understanding of the invention and are obvious to an average person with relevant knowledge of the art related to the invention. In addition, variations of the exemplary embodiments are possible where, for example, certain elements of the exemplary embodiments may be rearranged, omitted and replaced with equivalents or new ones may be added, and existing elements may be interconnected in a manner different from that described; provided that the different wiring is compatible with the technical effect that the elements of the invention have, being technical characteristics of the invention. Similarly, modification of the shape and dimensions of the illustrated parts is considered to be within the scope of protection of the present invention to the extent that such modifications are obvious to persons skilled in the relevant art and to the extent that such modifications are equivalent to the exemplary embodiments presented or do not add tangible and unexpected or non-obvious improvements to the technical result they offer. Thus, the present text is not intended to be limited only to the exemplary embodiments of the invention presented but is to be given the widest possible scope in accordance with the principles and novel features it discloses.

Unless otherwise specifically stated, it is the intention of the inventor to give to the words and phrases mentioned in the description of the invention and the claims the ordinary and generally accepted meanings attributed to the average person with relevant knowledge of the related art with the present invention.

The foregoing description of a preferred embodiment and best mode of carrying out the invention known to the applicant at the time of filing has been presented and is intended for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed and many modifications and variations are possible in light of the above teachings. The embodiment has been selected and described to better explain the principles of the invention and its practical application and to enable others skilled in the art to better utilize the invention in various application scenarios and modes of use and with various modifications as are appropriate to the specific use under consideration. Therefore, it is intended that the invention is not limited only to the specific details disclosed for carrying out the invention, but that the invention includes everything that falls within the scope of the appended claims.

Claims (24)

1. Fire-extinguishing hydraulic mortar for the production of fire-extinguishing suspension for use in fire extinguishing, for thermal insulation and cutting off oxygen supply and trapping of gaseous and solid combustion producers, which mortar comprises, at least one first material from a first class of materials, at least one second material from a second class of materials, and at least one third material from a third class of materials, which mortar is characterized by: the at least one first material from the first class of materials is selected from calcium compounds and magnesium compounds; the at least one second material from the second class of materials is selected from salts; the at least one third material from the third class of materials is selected from ferrous compounds and aluminosilicate compounds; calcium compounds are selected from calcium hydroxide, calcium oxide, and calcium carbonate; magnesium compounds are chosen between magnesium hydroxide and magnesium carbonate? salts are chosen between potassium oxide and sodium oxide? ferrous compounds are selected from iron(III) oxide and other iron oxides? aluminosilicates are chosen between silicon dioxide and aluminum oxide? and the at least one first material and sum of the at least one second material and the at least one third material is in a ratio ranging from about 2:8 wt. up to about 9: 1 c.v. in the mortar, the percentages of the materials add up to 100% and each of the materials is in the form of a grain with a maximum diameter equal to or less than 100 microns. 2. Fire mortar according to claim 1, wherein the at least one first material comprises all compounds from the first class of materials, the at least one second material comprises all salts from the second class of materials, and the at least one third material comprises all ferrous compounds and the aluminosilicate compounds from the third category of materials. 3. Fire mortar according to claim 2, wherein the percentages of the materials are 19.0%-85.45% for Calcium Hydroxide, 0.17%-0.765% for Calcium Oxide, 0.7%-3 , 187% for Calcium Carbonate, 0.03%-0.128% for Magnesium Hydroxide, 0.1%-0.47% for Magnesium Carbonate, 4.4%-0.55% for its Oxide Potassium, 3.2%-0.4% for Sodium Oxide, 1.2%-0.15% for Iron (III) Oxide, 62.8%-7.85% for Silicon Dioxide, and 8.4%-1.05% for Aluminum Oxide. 4. Fire mortar according to claim 2, wherein the percentages of the materials are 19.0% for Calcium Hydroxide, 0.17% for Calcium Oxide, 0.7% for Calcium Carbonate, 0.03% for Magnesium Hydroxide, 0.1% for Magnesium Carbonate, 4.4% for Potassium Oxide, 3.2% for Sodium Oxide, 1.2% for Iron (III) Oxide, 62.8 % for Silicon Dioxide, and 8.4% for Aluminum Oxide. 5. Fire mortar according to claim 2, wherein the percentages of the materials are 85.45% for Calcium Hydroxide, 0.765% for Calcium Oxide, 3.187% for Calcium Carbonate, 0.128% for Magnesium Hydroxide, 0. .47% for Magnesium Carbonate, 0.55% for Potassium Oxide, 0.4% for Sodium Oxide, 0.15% for Iron (III) Oxide, 7.85% for Silicon Dioxide , and 1.05% for Aluminum Oxide. 6. Fire mortar according to claim 2, wherein the percentages of the materials are 66.5% for Calcium Hydroxide, 0.6% for Calcium Oxide, 2.5% for Calcium Carbonate, 0.1% for Hydroxide of Magnesium, 0.3% for Magnesium Carbonate, 1.8% for Potassium Oxide, 1.3% for Sodium Oxide, 0.5% for Iron (III) Oxide, 22.9% for Silicon Dioxide, and 3.5% for Aluminum Oxide. 7. Fire extinguishing suspension for use in fire extinguishing for cooling, thermal insulation and cutting off oxygen supply and trapping of gases and solid combustion products, and for use on a surface to prevent and protect against fire by isolating the surface from atmospheric air preventing the surface from burning, which suspension comprises water and fire mortar according to any one of claims 1-6, in a ratio of from 9:1 to 7:3. 8. A method of preparing a homogenized fire extinguishing suspension according to claim 7, which method comprises the following steps: adding a fire-fighting mortar according to any of claims 1-6, to water, in a ratio of from 1:9 to 3:7; and stirring the suspension until it is homogeneous. 9. A fire extinguishing method using a homogenized fire extinguishing suspension according to claim 7, which method comprises the following steps: preparing the homogenized fire extinguishing suspension according to the method of claim 8; throwing the homogenized fire extinguishing slurry directly onto a burning surface, and at least until either (a) complete coverage of the burning surface by a mantle, where the mantle results from evaporation of water from the homogenized fire extinguishing slurry, and sintering and conversion of the fire extinguishing slurry, under the influence of thermal energy of the burning surface, in a cement-like mass of loose consistency (cement slag - clinker), or (b) complete extinguishment of the burning surface? wherein (i) the slurry mortar traps the water contained in the slurry and reduces evaporation of the water before it contacts the burning surface to achieve maximum cooling of the burning surface and bonding of the slurry to the burning surface, (ii) the mantle thermally insulates the burning surface and prevents its reheating, and (iii) the mantle isolates the surface from atmospheric oxygen, altogether extinguishing the burning surface and preventing its re-ignition. 10. A fire extinguishing method according to claim 9, wherein the homogenized fire extinguishing suspension is stirred continuously until it is poured. 11. A fire prevention and protection method using a fire extinguishing suspension according to claim 7, which method comprises the following steps: preparing a homogenized fire extinguishing suspension according to the method of claim 8; casting the homogenized fire-extinguishing slurry directly onto a surface for fire prevention and protection, and at least until the surface is partially covered by a mantle, where the mantle results from evaporation of water from the homogenized fire-extinguishing slurry, and agglomeration and conversion of the fire-extinguishing slurry into a solid refractory mass which isolates the surface from the atmospheric air preventing the burning of the surface. wherein (i) the slurry mortar traps the water contained in the slurry and reduces evaporation of the water before it contacts the surface to achieve maximum cooling of the burning surface and bonding of the slurry to the burning surface, (ii) the mantle thermally insulates the surface and prevents its heating, and (iii) the mantle isolates the surface from atmospheric oxygen, overall preventing the surface from igniting. 12. A fire prevention and protection method according to claim 11, wherein the homogenized fire extinguishing suspension is continuously stirred until it is poured. A fire extinguishing system (100) using the method of claim 9, which system (100) comprises: a tank (120) designed to be supplied with a fire extinguishing suspension according to claim 7, which suspension has been prepared according to claim 8; a pump (130) connected to an outlet (121) of the tank (120), which pump (130) is designed to drain the fire-extinguishing slurry from the tank (120) and supply the fire-extinguishing slurry under pressure to a hose (140); and a hose (140) connected to the pump (130) and designed to discharge the fire extinguishing slurry according to the method of claim 9. A fire extinguishing system (100) according to claim 13, wherein the tank (120) comprises an agitator (125) designed to agitate the fire extinguishing slurry to ensure continuous homogenization of the fire extinguishing slurry until it is discharged according to the method of claim 10 . A fire extinguishing system (100) according to claim 14, wherein the agitator (125) is transversely mounted on vertical walls of the tank (120). 16. A fire extinguishing system (100) according to any one of claims 13-15, wherein the fire extinguishing system (100) is installed in one of (a) a fixed installation, (b) a portable device, (c) a fire engine, and (d) ) aerial medium, and wherein in the case of the aerial medium the hose (140) is replaced by a port in the tank. 17. A fire extinguishing system (100) according to any one of claims 13-16 wherein the preparation of the fire extinguishing suspension is carried out according to the method of claim 8 in an independent barrel (150), which barrel (150) includes a stirrer (155), and then the fire extinguishing slurry is pumped from the barrel (150) into the container (120) of the system (100). A fire prevention and protection system (100) using the method of claim 11, which system (100) comprises: a tank (120) designed to be supplied with a fire extinguishing suspension according to claim 7, which suspension has been prepared according to claim 8; a pump (130) connected to an outlet (121) of the tank (120), which pump (130) is designed to drain the fire-extinguishing slurry from the tank (120) and supply the fire-extinguishing slurry under pressure to a hose (140); and a hose (140) connected to the pump (130) and designed to discharge the fire extinguishing slurry according to the method of claim 11. 19. A fire prevention and protection system (100) according to claim 18, wherein the tank (120) includes an agitator (125) designed to agitate the fire extinguishing suspension to ensure continuous homogenization of the fire extinguishing suspension until it is discharged, according to the method of claim 11. A fire prevention and protection system (100) according to claim 19, wherein the agitator (125) is transversely mounted on vertical walls of the tank (120). 21. A fire prevention and protection system (100) according to any one of claims 18-20, wherein the fire extinguishing system is installed in one of (a) a fixed installation, (b) a portable device, (c) a fire engine, and ( d) aerial medium, and wherein in the case of the aerial medium the hose (140) is replaced by a port in the tank. 22. A fire prevention and protection system (100) according to any one of claims 14-17 wherein the preparation of the fire extinguishing suspension according to the method of claim 4 takes place in an independent tank (150), which tank (150) includes a stirrer ( 155), and then the fire extinguishing slurry is pumped from the barrel (150) into the container (120) of the system (100). 23. Use of the fire extinguishing system (100), according to any of claims 13-15, in indoor, outdoor urban, outdoor industrial and agroforestry areas. 24. Use of the fire prevention and protection system (100), according to any one of claims 18-20, in indoor spaces, outdoor urban spaces, outdoor industrial spaces and agroforestry areas, where in the case of agroforestry areas the use of the system is to create a firewall.