ITMI931251A1 - FOAMING COMPOSITION TO REDUCE THE PRESSURE ASSOCIATED WITH THE SHOCKWAVE GENERATED BY EXPLOSIONS - Google Patents

Abstract

A foaming composition is described which is capable of forming foams that are particularly appropriate for reducing or weakening the pressure associated with the shock wave generated by a burst, comprising particular surface-active agents and, in order to increase the duration and multiplicity of use thereof, either polymers, or proteins, or polymers and proteins.

Description

"FOAMING COMPOSITION TO REDUCE THE PRESSURE ASSOCIATED WITH THE SHOCK WAVE GENERATED BY EXPLOSIONS"

DESCRIPTION

The present invention relates to a foaming composition capable of reducing or attenuating the pressure associated with the shock wave generated by explosions. Pi? in particular it relates to a foaming composition possibly containing proteins, polymers or proteins and polymers, in order to further increase the drainage time of the foam and to lengthen the average life of the foam itself.

It is known that a foam can? be defined as a physical system consisting essentially of the dispersion of a gas in a solution formed by a foaming liquid and water.

The parameters that characterize a foam are in principle a) the chemical composition used for the preparation, b) the expansion ratio (RE), i.e. the value of the ratio between the volume of foam produced and the volume of the liquid solution used to produce said foam, and c) drainage, i.e. the value of the time required for? the foam separates 25-50% of the solution used to prepare it.

The chemical composition has a certain influence on the expansion ratio, on the drainage of the foam and on the resistance to chemical attack by external agents. The value of the expansion ratio characterizes the smoothness and the plasticity? of the foam, and the value of the drainage time quantifies the greater or lesser resistance of the foam to spontaneous collapse and thermal shock. It is also known that the sudden variation of the thermodynamic parameters (pressure, temperature, specific volume, velocity of the gases) that occurs inside an explosive during the detonation of a charge, generates at the interface the explosive-surrounding medium, a shock wave that propagates spherically in the considered medium (air or in the case in question foam) with velocity? supersonic decreasing up to a certain distance from the charge, and therefore with speed? sonic.

Since? the explosive phenomenon no longer provides? energy to sustain the shock wave, as it moves away from the source (expansion point) the maximum pressure that characterizes it decreases, while the pressure decay time increases. By fixing in space a plane hit by the shock wave, the pressure, after a sudden increase, will decrease? over time with an exponential law.

In recent times, the foams have been thoroughly examined to evaluate their capacity? to attenuate the pressure associated with the shock wave generated by an explosion. This ability? it would be related to the physical transformations that accompany the destruction of the foam surrounding the explosive. In particular, part of the energy of the shock wave would be consumed as the work of transforming the foam into minute droplets of water and a subsequent amount of energy would then be used in the evaporation of these droplets. It has been evaluated that particular types of foams can absorb more in total? 90% of the pressure generated by an explosion.

From US-A-3 .976 .580? known is a fluid for extinguishing flames comprising an aqueous gel containing as a gelling agent a combination of polyacrylamide, in particular a mixture containing 0.5 parts of polyacrylamide and 2.7 parts of bentonite per 100 parts by weight of water. The resulting final product is applied to an area attacked by the flames to give a cold wet cover that inhibits the further spread of the fire.

In the DE-0S- 2.310 .078? described an extinguishing composition in the form of a gel which, as a gelling agent, contains bentonite or niontmorillonite. From EP-421.166? a process is known for the reclamation of containers of flammable substances, comprising the steps of generating fire-fighting foam, filling the container to be reclaimed with said foam, cutting said container and breaking down said foam for its subsequent disposal, in which it is possible to use all known foams currently on the market.

From IT-A- 22120A / 89? notes a foaming composition to be used to extinguish flames or suffocate fumes of acidic and / or toxic and / or flammable vapors, particularly suitable for inerting containers containing liquid, solid or muddy materials that emit acidic, toxic and / or flammable gases, including urea , ethylene glycol, an ethoxylated alcohol sulphate, carboxymethylcellulose sodium salt, a fatty alcohol and optionally a fluorinated surfactant and b iopolymers.

In all the literature mentioned there is therefore no mention of any foam capable of attenuating the shock waves that are generated in the case of explosions.

In the patent application IT-MI92A001563 in the name of the Applicant? disclosed is a foaming composition capable of reducing the pressure associated with the shock wave generated by explosions comprising carboxymethyl glycine, a clay and a foaming agent, in which the clay can be used. be bentonite, attapulgite, montmorillonite, sepiolite or verm iculite.

Even if this foaming composition? able to satisfactorily attenuate or reduce the pressure associated with the shock wave, the need for further improvements? always current, especially the need to find compositions that can be used more? times without the need to replace them or integrate them with fresh material. The purpose of the present invention was therefore to find a new foaming composition which was capable of providing a foam capable of dramatically reducing or attenuating the pressure associated with the shock wave generated by explosions and which could be used more effectively. sometimes without the need to change or integrate it. In particular, we wanted to find a new foam of the type just described, which possibly had an increased drainage time (as defined above), a longer average life. long and an elasticity? greater and that it was therefore safe and resistant over time, that is? that it could be safely applied to explosives that for various reasons cannot be detonated immediately.

This can? be, for example, the case of a charge which, by exploding, could cause damage in the immediate vicinity and which cannot? be safely removed or destroyed.

It has now been found that the intended purpose could be successfully achieved by means of a foaming composition. defined below.

In a first aspect, the present invention therefore provides a first foaming composition (a) suitable for providing a foam capable of visibly reducing or attenuating the pressure associated with the shock wave generated by an explosion, which composition? characterized in that it comprises: glycols and glycol ethers, an ethoxylated alcohol sulphate, ethoxylated and non-ethoxylated fatty alcohols, a mono or dietanoylamide of coconut, isobutyl alcohol and water. In a second aspect the invention provides a foaming composition (b) comprising the above-mentioned ingredients in association with a polymer or polymers.

In a third aspect the invention provides a foaming composition (c) comprising the ingredients mentioned for composition (a) and protein.

Finally, in a fourth and last aspect, the invention provides a foaming composition (d) comprising proteins and polymers.

As used herein, the term "protein" or "proteins" refers to hydrolysates of proteins in aqueous solution obtained in a known way from keratin and having molecular weights ranging from 1000 to 80,000.

The term "polymer" or "polymers" indicates polysaccharides in general and in particular of the galactomannan type, such as for example guar flour and / or carob flour hydroxylated or ethoxylated or as such.

For the production of the actual foam, the composition described above, suitably mixed with water, is mixed with air or with an inert gas, for example nitrogen, until 10-60 liters of foam are obtained per liter of solution used. Due to the particular composition, this foam has a very long drainage time, that is? high stability in time. When applied to an explosive, the foam tends to form as an absorbent shield that frener? and reduce? the shock wave generated by the explosion of said explosive.

It was surprising to find that already? with a small addition of proteins and / or polymers, which have the capacity? to form gel with water,? It is possible to obtain foams having an expansion ratio between 5 and 40, preferably 20, with drainage times of 50% ranging from 13 to 24 hours, generally 15 hours. Particularly effective yes? the addition of polymers has been demonstrated which, in accordance with the formulation object of the invention, are suspended in a medium which does not solubilize them, but which, once dissolved in water, are capable of providing solutions having very long drainage times. In a first preferred embodiment of the present invention, the foaming composition comprises from 40 to 80%, preferably from 50 to 65% by weight of ethoxylated sulphated alcohols; from 5 to 20%, preferably from 8 to 16% by weight of glycols and glycol ethers; from 1 to 3%, preferably from 1 to 2% by weight of fatty alcohols with 12-14 carbon atoms, from 10 to 25% of isobutyl alcohol, from 0.2 to 2% of coconut mono or diethane lamide and water to have 100%.

In a second preferred embodiment of the invention the foaming composition comprises: from 1 to 15% by weight of polymers; from 3 to 15% by weight of glycols and glycol ethers; 40 to 60, preferably 45 to 55% by weight of ethoxylated sulfate alcohols; 1 to 5%, preferably 1.5 to 2.3% by weight of fatty alcohols with 12-14 carbon atoms; from 10 to 25% by weight of isobutyl alcohol, from 0.2 to 0.8% of mono or diethane lamide of coconut and water to have 100%.

In a third preferred embodiment, the foaming composition comprises from 60 to 80% by weight of proteins, from 1 to 3% of metal salts, from 5 to 10% of glycols and from 5 to 10% of isobutyl alcohol and water to have 100%.

There? it should be remembered here that with metal salts we mean here the usual salts normally used for this purpose, for example zinc chloride and iron sulphate.

In a last preferred embodiment, the quantity? of proteins is decreased and the quantity? final is integrated by the polymers in quantity? variable between 1 and 15%.

In order to evaluate the effectiveness of the foams object of the present invention, explosion tests were carried out, the methodologies of which and the results of which are reported below.

For safety reasons, the tests were carried out in a 1 cubic meter metal tank consisting of A iron side walls, equipped with reinforcement belts, resting on a bottom consisting of an iron plate.

At the bottom of the tub, yes? supported an iron cylinder with a central hole, and on this cylinder you? placed the "target", consisting of a square of copper sheet above which a charge of TNT triggered with an electric detonator is maintained at a predetermined distance. The foam to be examined is then placed in the tank up to a level of 80 cm, so that the charge-target complex is completely immersed.

The charge then explodes, the copper square is recovered and the deformation or complete detachment of the central area is evaluated.

By measuring the volume of the flaring occurred, and based on the mechanical characteristics of resistance to deformation of the material,? It was possible to calculate the pressure that produced the def ormation.

Comparing the theoretical pressures with those obtained, yes? found that the pressure decrease of the explosion occurred in the foam varies between 90 and 98%.

To confirm the results obtained by measuring the deformations of the copper sheet,? An experiment was carried out with shock wave pressure recordings using piezoelectric pressure transducers.

Using the devices described above, burst tests were carried out in water, air and foam having different densities. with loads of compressed TNT of increasing weight. Yup ? could so? make sure the following!

a) did all the experiments carried out in the presence of foams produce a noise in the surrounding environment? and a much lower "puff" effect compared to similar tests performed in air; and b) among the various types of foams examined, the foam with a higher water content (expansion ratio between 10 and 20) is characterized by the greater absorption oscillating between 90 and 98%.

EXAMPLE 1

In a reactor equipped with stirrer, thermometer, feeders and a heating system, 4.11 kg of water, 14.16 kg of ethoxylated lauryl alcohol with 2 moles of ethylene oxide and sulphated, sodium salt, 8.1 kg are loaded of a fatty alcohol (8-10 C) ethoxylate (1 mole) sulfated, 8.76 kg of a fatty alcohol (9-11 C) ethoxylate (2 moles) sulfated, 7.8 kg of buti1dig 1ico1e, 600 g of alcohol with 14 carbon atoms, 660 g of alcohol with 12 carbon atoms, 360 g of coconut monoethane 1amide and 150 g of antifermentative. The mixture is heated to 50 ° C, 30 ml of HC1 are added to bring the pH to 7, then 300 g of hydroxypropylene guar flour and 600 of isobutyl alcohol are added. It is kept for 1 hour at 50 ° C, then 6.6 kg of carob flour and 7.9 kg of isobutyl alcohol are added. It is stirred for another 30 minutes, then the product is discharged. Final pH 6.8 value. The viscosity? final measured at 20 ° C with a Brookfield viscometer? of 3500 cps. The foaming composition is bound to 5-6% in water to give a solution with viscosity? after 20 minutes of 320 cps and after 30 minutes of 600 cps.

EXAMPLE 2

In the reactor described in Example 1, 6.51 kg of water, 14.11 kg of ethoxylated C12-14 alcohol (2 moles) sulphated, 8.1 kg of ethoxylated alcohol (1 mol) C8-C10 sulphated, 8, 76 kg of ethoxylated alcohol (2 moles) sulphated C9-C11, 5.4 kg of isobutyl alcohol, 600 g of C14 alcohol, 660 g of C12 alcohol, 360 g of coconut diethane lamide, 150 g of anti-fermentation agent and pH 7 with 30 g of HCl. It is heated to 50 ° C, then 300 g of guar flour and 600 g of isobutyl alcohol are added. It is kept at 50 ° C for one hour, then 6.6 kg of guar flour and 7.8 kg of isobutyl alcohol are added. It is kept for half an hour at the temperature mentioned above, then the product is discharged. Its stickiness? measured at 20? C? of 3000 cps, while in a 5% solution in water? of 280 cps after 10 minutes and of 440 cps after 30 minutes.

EXAMPLE 3

Other compositions have been prepared using the same reactor described above and only concentrated and non-dissolved carob flour, or a quantity? variable of guar flour and proteins or a concentrated liquid containing only proteins. In the case of the use of proteins only, zinc chloride or iron sulphate were added, and no sulfated ethoxylated alcohols were used. the other ingredients. The viscosity? of the final product? generally between 500 and 5000 cps, while in its normal use at 5-6% in water it provides solutions having viscosity? oscillating between 200 and 800 cps. Generally the relationship between polymers and proteins? of 20:80.

All the compositions mentioned above provide with air or inert gas an optimally active foam to reduce or extensively attenuate the pressure associated with the shock wave generated by an explosion.

Logically, any person skilled in the art could make some modifications or variations to the invention, for example by playing on the polymer, on the protein or on the various components of the foaming composition. Since? it would be long and tedious to list in particular all fatty alcohols, or glycols or other surfactant components, any variation falling within the concept of the present invention must be considered absolutely obvious and predictable.

Claims (10)

CLAIMS 1. Foaming composition capable of forming a foam with air or an inert gas that can be used to reduce or attenuate up to 98% the pressure associated with the shock wave generated by explosions, characterized in that it includes: 40 to 80%, preferably 50 to 65% by weight of ethoxylated sulfated alcohols, 5 to 20%, preferably 8 to 16% by weight of glycols or glycol ethers, 1 to 3%, preferably 1 to 2% by weight of fatty alcohols with 12-14 carbon atoms, 10 to 25% by weight of isobutyl alcohol, 0.2 to 2% by weight of coconut mono or diethane, and water to have 100%. 2. Foaming composition capable of forming a foam with air or an inert gas that can be used to reduce or attenuate up to 98% the pressure associated with the shock wave generated by explosions, characterized by the fact that it includes: from 1 to 15% by weight of polymers, 3 to 15% by weight of glycols or glycol ethers, 40 to 60%, preferably 45 to 55% by weight of sulfated ethoxylated alcohols, 1 to 5%, preferably 1.5 to 2.3% by weight of fatty alcohols with 12-14 carbon atoms, 10 to 20% by weight of isobutyl alcohol, 0.2 to 2% by weight weight of coconut mono or diethane 1amide, e water up to 100%: 3. Foaming composition capable of forming with air or with an inert gas a foam that can be used to reduce or attenuate up to 98% the pressure associated with the shock wave generated by explosions, characterized in that it includes: 60 to 80% by weight of protein, 1 to 3% by weight of metal salts, from 5 to 10% by weight of glycols and glycol ethers, from 5 to 10% by weight of isobutyl alcohol, where the rest 100%? given by water. TO. Foaming composition according to claim 2, characterized in that the polymers are selected from hydroxy or ethoxylated guar or carob flour and guar or carob flour as such. 5. Foaming composition according to claim 3, characterized in that the proteins are hydrolyzed of proteins in aqueous solution obtained in a known way from keratin with molecular weights ranging from 1000 to 80,000. 6. Foaming composition according to claim 3, characterized in that the metal salts are zinc chloride and iron sulphate, 7. Foaming composition according to claims 2 or 5, characterized in that the quantity? 1-15% of polymers? divided between polymers and proteins in the polymers: proteins ratio in particular 20:80. 8. Method for reducing or attenuating the pressure associated with the shock wave generated by an explosion, comprising covering the explosive with a foam prepared from a composition according to any one of claims 1 to 7, used at 5-6% in water to give solutions having viscosity? variable between 200 and 800 cps, which is mixed with air or with an inert gas, in particular nitrogen, to obtain 10-60 liters of foam per liter of solution used, characterized by the fact that the foaming composition includes ethoxylated sulphated alcohols, glycols o glycol ethers, fatty alcohols with 12-14 carbon atoms, isobutyl alcohol, mono or dietano1am ide of coconut, in which to increase the life of the foam and ensure its repeated use without having to replace it, add polymers, proteins or po limers and proteins. 9. Method according to claim 8, characterized by? the fact that the polymers are selected from the group comprising hydroxylated or ethoxylated hydroxylated or ethoxylated guar or carob flour and carob or guar flour as such. 10. Method according to claim 8, characterized in that the proteins are selected from protein hydrolyzates obtained in a known way from keratin with molecular weights of 1000-80,000 with the addition of metal salts selected from zinc chloride and iron sulphate.