KR20190137461A - High foaming compositions for foam extinguishing agents used in compressed air foam system - Google Patents

Abstract

The present invention relates to a high foamable foaming solution composition for a compressed air foaming system. The foaming solution composition of the present invention can be used as the solution itself without separately diluting an undiluted solution with water and is mixed with an antifreeze such that several complex devices such as a heating device, etc. are not required. Therefore, the foaming solution composition of the present invention can be used as a portable small fire extinguisher that does not require a separate additional device such as a diluting device and the heating device and can be used at a temperature of -20°C.

Description

High foaming compositions for foam extinguishing agents used in compressed air foam system}

The present invention relates to a highly foamable foaming solution composition for a compressed air saturation system.

Foam is generated when air is injected after mixing foam fire extinguishing agent with water. The resulting foam is a collection of fine bubbles lighter than oil to cover the surface of the combustion products to block the contact with the air, and to have a choking effect, the water used together with the cooling effect. In other words, the fire extinguishing agent fights fires by the choking effect and the cooling effect. Fire extinguishing agents are most effective for extinguishing oil fires because they can choke on the surface of oil, but can also be used for general fires. In general, water alone is used for the extinguishing of flammable liquids in which the fire extinguishing effect is weak or in which the fire may be increased by water.

Fire extinguishing, the main effect of foam fire extinguishing agents, is the suffocation effect caused by the foam covering the surface of flammable substances and the cooling effect by a significant amount of water. In addition, the high-foamed fabric has a very large volume, and can be expected to have a fire extinguishing effect such as blocking the movement of heat by convection and radiation, exhausting ambient air, and suppressing the generation of flammable vapor. The fabric is composed of a thin film, but because it is tacky and heat resistant, it exhibits a digestive effect.

There are two types of fabric guns (also known as air guns), in which air is the core by stirring and mixing air with carbon dioxide as a nucleus. Chemical guns are not currently used and generally the latter means machine guns. The machine cloth can be divided into low expansion cloth, medium expansion cloth, and high expansion cloth according to expansion ratio. Korea is divided into two types: low-expansion bubble with expansion ratio less than 20 and high-expansion bubble with more than 80. Low-expansion fabrics include proteins, fluorinated proteins, synthetic surfactants, aqueous membrane fabrics, and alcohol-resistant fabrics, and high-expansion fabrics include synthetic surfactants.

 Requirement of extinguishing agent is as follows.

1. Excellent ability to remove one or more of the four components of combustion.

2. Low price

3. Have storage stability

4. Low pollution to the environment / No toxicity to the human body

Conventional foaming equipment is a fire extinguishing equipment used for a fire of a flammable liquid which is ineffective by the water extinguishing method or may expand the fire by waterproofing the water. In other words, the combustion surface is covered with a cloth to obtain a suffocating effect or digested as a cooling effect by moisture contained in the cloth. This equipment is equipped with an aspirator type that forms a bubble through the four screen after the foam solution is mixed with air through the flow chamber, and the blower is blown out by using a blower when the catcher solution is injected from the nozzle. There is a blower type that forms a fabric while passing through it. However, this type of saturation equipment is difficult to form a high-quality gun because it uses the contaminated air at the fire site to expand the gun. In addition, it is difficult to infiltrate the fire plume in a storage warehouse with a high ceiling because it can not be waterproof at a high spray rate, there is a disadvantage such as having a large number of water and artillery damage.

Compressed Air Foam System (CAFS) is a foaming device that injects compressed air into a foam solution mixed with water and foaming agents in a unit to generate foam. It is a device that radiates bubbles containing compressed air from the common window, and it exerts overwhelming extinguishing power and achieves breakthrough evolution in comparison with conventional bubble spinning such as loss by water damage, operability of hose, cooling ability, pressure loss, range have. Compressed air fire extinguishing system is mainly composed of a pressure to generate pressure air, an electric bubble pump for supplying the drug, a drug tank for loading the drug, and a mixing unit for mixing the water and the drug and compressed air.

The characteristics of the compressed air saturation system are as follows:

1. Reduction of weight: From the flow of the bubble solution and the compressed air through the water discharge hose, the weight is very light compared to the weight when only water flows, and the burden of the fire extinguishing work can be reduced.

2. Prevention of damage: With the function of compressed air, more than 1450 L of extinguishing foam can be produced and discharged from 70 L of water. The maximum expansion ratio is about 20 times. The amount of water required for extinguishing can be reduced, preventing the loss caused by flooding.

3. Breakthrough cooling effect: In order to forcibly foam by compressed air in the mixing unit, the bubble upon spinning has a large surface area and a thin uniform film, and can achieve 5 times the cooling effect compared to water.

4. Wet foam and dry foam: By varying the ratio of water in the digestive foam, it continuously discharges the foam state from the highly permeable moisture foam (Wet foam) to the sticky moisture foam (Dry foam). Can change.

5. Direct fire extinguishing: Wet foam range is equal to or greater than that of water only, and high cooling foam can be injected directly to fire extinguishing point. (Direct digestion).

6. Combustion prevention: Dry foam has a high percentage of compressed air, so it has a low moisture content, so it can stick to vertical walls such as buildings, effectively blocking heat of combustion. (Burn prevention)

Meanwhile, the foaming agents used for the compressed air saturation system and the general saturation device are diluted with a concentration of 1%, 3% or 6% in water, using a high concentration of various surfactants and auxiliaries. It is a method of extinguishing by mixing the foam and foaming. However, this method requires a device capable of storing or supplying water for diluting the stock solution of the phos, and also requires a heating device that does not freeze at temperatures below freezing during the winter season. There is also a need for a device capable of mixing a concentrated concentration of the concentrated chemical solution at a predetermined ratio.

In the present invention, the saturating solution is a method of using the solution itself without diluting the stock solution separately in water, and the cryoprotectant is mixed to provide a saturating solution composition which does not require various complicated devices as described above.

The present inventors have made diligent research efforts to develop a saturation solution composition which does not require various complicated devices such as when using a conventional saturation agent. As a result, the present inventors developed a saturation solution containing a surfactant, glycerin or propylene glycol, and formic acid. The saturation composition of the present invention can use the solution itself without dilution in water separately. In addition, the cryoprotectant is mixed so that no complicated device such as a dilution device or a heating device is required.

Accordingly, an object of the present invention is to provide a highly foamable foaming solution composition for a compressed air saturation system.

One aspect of the invention provides a composition comprising (a) a surfactant at a concentration of 0.5-2% (v / v) with respect to the total composition; (b) a biodegradable low toxicity cryoprotectant, comprising: polyhydric alcohol at a concentration of 15-35% (v / v) with respect to the total composition; (c) an antifoaming agent having a digestive ability, formic acid at a concentration of 3-13% (w / w) based on the total composition; And (d) water, the present invention relates to a highly foamable foaming solution composition for a compressed air saturation system.

The present inventors have diligently researched to develop a saturation solution composition that does not require various complicated devices, such as when using a conventional saturation chemical. As a result, the saturation solution containing a surfactant, glycerin or propylene glycol, and formic acid Developed. The saturation composition of the present invention can use the solution itself without dilution in water separately. In addition, the cryoprotectant is mixed so that many complex devices such as dilution and heating devices are not required.

The saturating composition of the present invention is characterized by the general use of saturating solution solutions for surfactants, the use of non-toxic biodegradable glycerin and / or propylene glycols as antifreezing agents, and sodium formate as foaming agents and plasticizers. Formic acid is a low-molecular-organic acid salt that is biodegradable and non-toxic, so it is not only suitable for use as a saturating solution, but also has a digestive function and promotes foaming. In addition, it increases the durability to maintain the bubble state, delays the reduction rate caused by the bubble, and acts as a bubble activator to maintain the foam state, thereby suppressing the possibility of fire extinguishing and re-ignition.

The saturated solution composition of the present invention may include a surfactant at a concentration of 0.5-2% (v / v) based on the total composition. According to one embodiment of the invention, the surfactant is at least one surfactant selected from the group consisting of anionic surfactants, amphoteric surfactants and nonionic surfactants.

Anionic surfactants include, for example, sulfate anionic surfactants, fluorine anionic surfactants, sulfonate anionic surfactants, phosphate anionic surfactants, carboxylate anionic surfactants, and mixtures thereof. Sulfate-based anionic surfactants include, for example, sodium lauryl sulfate (SLS), sodium laureth sulfate (SLES), tee lauryl sulfate, M.P lauryl sulfate, thiapieira Urilsulfate and mixed compositions thereof. Fluorine-based anionic surfactants include, for example, Zonyl FS-62, Zonyl FSA, Zonyl FSE, Zonyl FSJ, Zonyl FSP, Zonyl TBS, Zonyl UR and mixed compositions thereof.

Amphoteric surfactants include alkyl aminopropyl betaines, alkyl dimethyl betaines, alkyl monoampoacetates, alkyl ampodiacetates, and mixed compositions thereof.

Nonionic surfactants include alkyl polyalkylene glycols, alkyl aryl polyalkylene glycols, alkyl dimethylamine oxides, di-alkyl methyl amine oxides, alkyl aminopropyl amine oxides, alkyl glucamides, alkylamines and mixtures thereof. .

According to another embodiment of the present invention, the surfactant is a component having biodegradability without environmental hazards such as toxicity, sulfide-based or fluorine-based surfactants as anionic surfactants, betaine as a zwitterionic, nonionic Alkanolamide surfactants or a mixture composition thereof can be used as the surfactant.

The alkanolamide-based surfactant is fatty acid alkanolamine, for example, alkanolamide (fatty acid alkanolamide), ethoxylated fatty acid alkanolamide (ethoxylated fatty acid). alkanolamide), fatty amine oxide, fatty amido amine oxide, or mixtures thereof.

According to another embodiment of the present invention, the surfactant is an anionic surfactant, for example, sodium lauryl sulfate (SLS), sodium laureth sulfate (SLES), thy lauryl sulfate, MIPA lauryl sulfate, TF ailauryl sulfate or a mixed composition thereof can be used. According to certain embodiments of the present invention, the anionic surfactant may use sodium lauryl sulfate (SLS), sodium laureth sulfate (SLES), or a mixed composition thereof.

The saturating solution composition of the present invention is a biodegradable low toxicity cryoprotectant, and may include polyhydric alcohol at a concentration of 15-35% (v / v) based on the total composition. According to one embodiment of the present invention, the saturating solution composition of the present invention may include a polyhydric alcohol at a concentration of 15-32% (v / v) with respect to the total composition. According to another embodiment of the present invention, the saturated solution composition of the present invention may include a polyhydric alcohol at a concentration of 22-35% (v / v) with respect to the total composition. According to another embodiment of the present invention, the saturated solution composition of the present invention may include a polyhydric alcohol at a concentration of 22-32% (v / v) based on the total composition.

According to one embodiment of the present invention, the polyhydric alcohol may include a dihydric alcohol, a trihydric alcohol or a mixture thereof. According to another embodiment of the present invention, the polyhydric alcohol may include one or more polyhydric alcohols selected from the group consisting of glycerin, propylene glycol and ethylene glycol. According to certain embodiments of the present invention, the polyhydric alcohol may include glycerin and propylene glycol, or glycerin and ethylene glycol.

When the saturating solution composition of the present invention contains glycerin and propylene glycol, or glycerin and ethylene glycol as polyhydric alcohols, the content of propylene glycol and sodium formic acid or ethylene glycol and sodium formic acid is maintained at a constant weight percent relative to the total composition. Can be used. This is because the total amount of glycol and formic acid is proportional to the pour point-to maintain the same pour point. For example, the content of propylene glycol and formic acid or ethylene glycol and formic acid may be included in an amount of 15% by weight based on the total composition.

The saturating solution composition of the present invention is a foaming agent having a digestive ability, and may include sodium formic acid at a concentration of 3-13% (w / w) based on the total composition. As can be seen in the embodiment of the present invention, the content of the formic acid is less than 3% (w / w) concentration of foaming rate is high but the reduction rate is faster, thereby reducing the extinguishing performance. In addition, when the formic acid content is more than 13% (w / w) concentration foaming rate is sharply reduced and the reduction rate is also fast. Therefore, it can be seen that the extinguishing performance is lowered at a concentration of 13% (w / w) or more.

According to another embodiment of the present invention, the saturating solution composition of the present invention may include formic acid at a concentration of 3-10% (w / w) based on the total composition. According to another embodiment of the present invention, the saturating solution composition of the present invention may include sodium formic acid at a concentration of 10-13% (w / w) based on the total composition. According to certain embodiments of the present invention, the saturating solution composition of the present invention may include formic acid at a concentration of 10% (w / w) based on the total composition.

The saturating solution composition of the present invention can be prepared by dissolving a surfactant, a polyhydric alcohol, sodium formic acid and other additives in water. In the present invention, in order to compare the expansion ratio according to the content of sodium formic acid, 25% reduction time and extinguishing performance, the concentration of glycol is fixed after fixing the active ingredient concentration of the surfactant to 1% concentration and the amount of glycerin as a cryoprotectant. When combined with the amount of, the total amount was the same (Example 1-5: 15 wt%). This is to maintain the same pour point at -20 ° C since the sum of the two components is proportional to the pour point. That is, the highly foamable foaming solution composition for a compressed air saturation system of the present invention was to maintain the content of glycol and sodium formic acid to be able to use even at a temperature of minus 20 ℃.

According to one embodiment of the present invention, the preparation of the saturation composition solution is dissolved in the formic acid after dissolving the formic acid first after measuring the active ingredient (surfactant, polyhydric alcohol and sodium formic acid) and the remaining amount of water so that the total solution of 1kg The saturation solution is prepared by measuring the concentration of the active agent and the cryoprotectant by concentration and stirring for about 10 minutes.

The saturating solution composition of the present invention may further include an additive, for example, hexylene glycol, triethylene glycol monobutyl ether, diethylene glycol monomethyl ether, diethylene glycol monoethyl ether, diethylene as a foaming aid Glycol monobutyl ether, propylene glycol monomethyl ether, dipropylene glycol monomethyl ether, and the like.

According to an embodiment of the present invention, the composition of the present invention may include water in the total composition of the remaining weight%, except for the surfactant, polyhydric alcohol and sodium formic acid.

The features and advantages of the present invention are summarized as follows:

(a) The present invention relates to a highly foamable foaming solution composition for a compressed air saturation system.

(b) The saturating solution composition of the present invention can use the solution itself without diluting the stock solution in water separately, and because the cryoprotectant is mixed, various complicated devices such as a heating device are not required.

(c) Therefore, the saturating solution composition of the present invention can be used for a portable small fire extinguisher that does not require any additional device such as a dilution device and a heating device.

(d) The saturating solution composition of the present invention can be used even at a temperature of minus 20 ° C.

Hereinafter, the present invention will be described in more detail with reference to Examples. These examples are intended to illustrate the present invention in more detail, and it is apparent to those skilled in the art that the scope of the present invention is not limited by these examples according to the gist of the present invention.

Throughout this specification, unless otherwise indicated, “%” used to indicate the concentration of a particular substance is solid / solid (weight / weight)%, solid / liquid (weight / volume)%, and Liquid / liquid is (volume / volume)%.

Example

The compressed air bubble digestion solution of the present invention was prepared with the following composition and content (see Table 1 below).

- Example Comparative example Formulation example One 2 3 4 5 One 2 Other company's product1 Other company's 2 Surfactants SLS 0.5% 0.5% 0.5% 0.5% 0.5% 0.5% 0.5% - - Surfactants SLES 0.5% 0.5% 0.5% 0.5% 0.5% 0.5% 0.5% - - Cryoprotectants glycerin 20% 20% 20% 20% 17% 17% 17% 1% solution 1% solution Cryoprotectants Propylene glycol 14% 12% 5% 2% 0% 5% 2% - - Foam activator Formic acid One% 3% 10% 13% 15% Formic acid
10% potassium Formic acid
Potassium 13% - - Low foaming performance Expansion rate 23.1 times 20.9 times 18.6 times 15.2 times 9.65 times 11.8 times 12.3x 12.5 times 10.6 times Low foaming performance 25% reduction time 9'31 " 14'29 " 16'38 " 12'19 " 6'38 " 6'17 " 6'37 " 7'45 " 8'59 " High foaming performance Fortune Collection Time 1'26 " 1'07 " 57 " 1'06 " 1'23 " 1'20 " 1'17 " 1'15 " 1'13 " High foaming performance Expansion rate 756 times 723 times 676 times 627 times 487 times 517 times 535 times 575 times 637 times High foaming performance 25% reduction time 12'11 " 17'13 " 25'35 " 21'12 " 16'21 " 10'57 " 15'06 " 11'02 " 13'06 "

* Other company's product: Korean Registered Patent No. 10-1724583 Compressed air saturation equipment and 1% synthetic surfactant saturation solution that can be used in general saturation equipment, Example 2 composition

* Other company's product # 2: Republic of Korea Patent No. 10-1366308 Eco-friendly foaming agent composition, Example 1 composition

On the other hand, in order to compare the expansion ratio, 25% reduction time and the extinguishing performance according to the content of the formic acid sodium (foaming agent) which is a feature of the present invention, a sample was prepared as follows. After fixing the active ingredient concentration of the surfactant to a concentration of 1% and the amount of glycerin as a cryoprotectant, the total amount of glycol was the same when combined with the amount of formic acid (15 wt% of the total composition). This is to maintain the same pour point at -20 ° C since the sum of the two components is proportional to the pour point.

The preparation of the sample measured the remaining amount of water other than the active ingredient so that the total solution was 1 kg. Sodium formic acid was first dissolved, and then, measured by concentrations in the order of the surfactant and the antifreeze agent, and stirred for about 10 minutes to complete the saponification solution.

Experimental Example

In order to compare the performance of the fire extinguishing solution for compressed air of the present invention, a test was conducted as follows.

One. Foaming performance test

The test was carried out in accordance with the ISO 7203 Fire Extinguishing Agent Test Method of Fire Fighting Agents and the Ministry of Internal Affairs Notice No. 9, Type Approval and Testing Techniques of Fire Fighting Agents. The test results are shown in Table 1 above.

(1) Low foaming performance evaluation

Each of the above-mentioned liquid solutions (1% concentration) at 20 ± 2 ° C is foamed using a standard foam nozzle at a water pressure of 0.7 MPa and a water resistance of 10 L per minute, and the volume is stored at a position about 10 cm away from the tip of the nozzle. The bags (bubbles) were collected in dog collection containers. At this time, the amount of cells collected in the collecting container was measured by the number of g, and the expansion coefficient was calculated according to the following formula.

In addition, the time was measured from when the foam (bubble) was filled to the collecting container, and the time required for reducing the 25% of the aqueous solution from the foam (bubble) was measured.

[Calculation 1]

Expansion rate =

Q: Number of releases per 1 minute 발포 of foaming machine (ℓ)

S: Bubble collection period (seconds)

V: Capacity of catcher container (ℓ)

(2) High foaming performance evaluation

Each of the above-mentioned packaging solutions (1% concentration) at 20 ± 2 ° C was subjected to a 2m X 2m X 1m gold mesh container using a standard foaming device under the conditions of a water pressure of 0.1 MPa, water resistance of 6 L per minute, and air volume of 13 cm2. After foaming, the filling time of the filling was measured, and then the expansion rate and the time taken for the collection were measured. In addition, the time required for the reduction of 25% of the aqueous solution from the blister (bubble) filled in the gold network was measured. At this time, the expansion coefficient was taken as the arithmetic mean value obtained by measuring the high foaming performance twice according to the above formula 1.

(3) Evaluation result of foaming performance

As can be seen from the results in Table 1, when the concentration of sodium formic acid is 10%, the foaming ratio is high, the reduction rate was found to be the slowest. As a result, when the concentration of formic acid was 10%, it was found that the foaming state was the best and the digestion rate was the fastest.

When the concentration of formic acid was less than 3%, the foaming ratio was high but the reduction rate was high, and the digestion performance was weakened. When the concentration of formic acid is more than 13%, the expansion ratio is rapidly lowered and the reduction rate is also faster, which indicates that the extinguishing performance is lowered.

In the comparative example, the experiment was conducted using potassium formate at the same concentration instead of sodium formate. When potassium formate was used, it was not as effective as sodium formate, and the composition of the present invention was found to have a good foaming ratio and excellent extinguishing performance when compared to commercially available products.

2. Digestive Performance Test

In order to measure the extinguishing performance of the saturating drugs of Examples and Comparative Examples of Table 1, first, each of the saturating drugs was a water-containing aqueous solution (saturated chemicals Stock solution 중량 1% by weight and water 99% by weight). Diluted with) to prepare. The test results are shown in Table 2 below.

(1) Low foaming fire extinguishing performance

The low-foam B fire extinguishing performance test was carried out in accordance with the Type Approval of the Fire Extinguishing Agent and the Technical Standards Test Regulation (KOFEIS 0103) presented by the Korea Fire Industry and Technology Institute.

After putting 320L of water and 200 ± 5L of n-Heptane into the B-grade fire model, the lamp was turned on, and after 1 minute, the aqueous solution of 20 ± 2 ° C. was spun away from the fire source for 8 minutes. At this time, the foam was completely formed, and the fire was recorded (fire time) until the time when the foam was applied to the fire and subsequently fired. In addition, after 8 minutes of foaming, the igniter was closed for 12 minutes, and if the flame was close to the surface, it was observed whether it re-ignitioned or whether it was sealed. In addition, after exposing the fuel surface to a square with a length of 15 cm in the center of the foam surface, the fire surface was lit again, and then fired again to measure the extinguishing performance.

(2) High foaming fire extinguishing performance

The firefighting performance test was carried out first in accordance with the Type Approval of the Fire Fighting Agents and the Technical Testing Standards (KOFEIS 0103) proposed by the Korea Fire Industry and Technology Institute.

In the high-exposure B-grade firepower model, a certain amount of water and gasoline (n-Heptane) were injected, and the net was immediately enclosed. Then, the fire model fired and fired the standard foaming device at the same time to deliver only the catching solution, but after 30 seconds, it fired and fired. At this time, the time to extinguish was measured. In addition, after 2 minutes and 30 seconds of fire extinguishing, foaming was stopped, and after 3 minutes of fire extinguishing, the presence of flame was confirmed.

Example Comparative example Formulation Example One 2 3 4 5 One 2 Other company's product1 Other company's 2 Low foaming
Digestive performance
(B class fire) Digestion time 1'52 “ 1'29 “ 1'03 “ 1'13 “ 1'49 “ 1'53 “ 1'39 “ 1'42 “ 1'51 “ Reignition has exist none none none none none none none none High foaming
Digestive performance
(B class fire) Digestion time 26 “ 21 “ 16 “ 19 “ 21 “ 22 “ 24 “ 23 “ 36 “ Reignition has exist none none none none none none none none

* Other company's product: Korean Registered Patent No. 10-1724583 Compressed air saturation equipment and 1% synthetic surfactant saturation solution that can be used in general saturation equipment, Example 2 composition

* Other company's product # 2: Republic of Korea Patent No. 10-1366308 Eco-friendly foaming agent composition, Example 1 composition

Claims (4)

(a) surfactant at a concentration of 0.5-2% (v / v) with respect to the total composition;
(b) polyhydric alcohols at a concentration of 15-35% (v / v) with respect to the total composition;
(c) formic acid at a concentration of 3-13% (w / w) relative to the total composition; And
(d) A highly foamable foaming solution composition for a compressed air saturation system comprising water.
The saturating solution composition of claim 1, wherein the surfactant comprises at least one surfactant selected from the group consisting of anionic surfactants, amphoteric surfactants, and nonionic surfactants.
The saturating solution composition of claim 1, wherein the polyhydric alcohol comprises one or more polyhydric alcohols selected from the group consisting of glycerin, propylene glycol and ethylene glycol.
The saturating solution composition of claim 1, wherein the surfactant is an anionic surfactant, and the polyhydric alcohol is glycerin and propylene glycol, or glycerin and ethylene glycol.