JP2017086519A - Fire inhibiting method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To inhibit and extinguish fire, especially fire in a deep part.SOLUTION: A method for inhibiting fire in a combustible accumulated place 3 surrounded with a peripheral wall 1 includes: discharging a seal layer forming agent containing gel, a non-inflammable material or a fire retardant, and a water-soluble inorganic matter, from above combustible deposits 5 in the combustible accumulated place 3; and forming a block seal layer 13 covering the whole surface of the combustible deposits. As for the gel, for instance, a substance with thixotropic nature can be selected. It is possible to jet steam S or fire extinction gas G from the bottom side of the combustible accumulated place 3.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a method for suppressing a fire that occurs in a combustible deposit area surrounded by a peripheral wall.

  Combustible materials such as garbage are collected in combustible collection sites, for example, pits of garbage collection factories, and incinerated, etc., but lighters and pyrotechnics are mixed in the collected garbage. If this happens, a spark may occur and a fire may occur in the pit. In addition, a fire may occur in the pit through the process of waste oxidation, heat generation, heat storage, temperature rise, and ignition.

  When the fire occurs, the fire is suppressed and extinguished by emitting a water-based fire extinguishing agent such as water or foam or a gas fire extinguishing agent from above the combustible deposit in the pit.

  However, the water-based fire extinguishing agent and the gas-based fire extinguishing agent can reach the upper layer side of the combustible deposit, but it is difficult to penetrate into the deep layer portion (the middle layer portion and the lower layer portion). . Therefore, when there is a fire source in the deep layer, fire suppression is difficult.

  Therefore, in order to solve the above-mentioned problem, fire extinguishing foam is released into the pit to cover the surface of the combustible deposit with the fire extinguishing foam, and inert gas is released from the peripheral wall of the pit, thereby There is a method of suppressing and extinguishing a surface fire and a deep layer fire (for example, see Patent Document 1).

JP 2003-190313 A

  In the conventional example, the fire-extinguishing foam covering the surface of the combustible deposit is extinguished over time and by heating due to the combustion of the combustible, so that it is difficult to maintain the sealed state by one discharge. . Therefore, since the said combustible deposit and air cannot be interrupted | blocked completely, the surface fire of the combustible deposit and the deep layer fire cannot be suppressed and extinguished by the suffocation effect.

  In view of the above circumstances, an object of the present invention is to make it possible to suppress and extinguish a fire, particularly a deep layer fire.

  The present invention is a method for suppressing a fire in a combustible deposit site surrounded by a peripheral wall, from above the combustible deposit in the combustible deposit site, a gel, a non-combustible material or a flame retardant, and a water-soluble inorganic substance. And a barrier seal layer covering the entire surface of the combustible deposit is formed.

  The gel of the present invention is a substance having thixotropic properties. The present invention is characterized in that water vapor is injected from the bottom side of the combustible deposit site. The present invention is characterized in that a fire extinguishing gas is radiated from the bottom side of the combustible deposit site.

Since the present invention is configured as described above, the following remarkable effects can be obtained.
(1) The entire surface of the combustible deposit in the combustible deposit site is covered with a shut-off seal layer containing gel, a non-combustible material or a flame retardant, and a water-soluble inorganic substance (such as sodium silicate), thereby providing a sealed state. Therefore, the contact between the combustible deposit and the air can be blocked.

(2) When the gel is emitted to the surface of the combustible deposit, almost all of the gel adheres to the surface of the combustible deposit without entering the inside of the combustible deposit. Can be covered with the gel (blocking seal layer).

(3) When the gel receives high-temperature fire heat, the water evaporates, and when further heated, water-soluble inorganic substances (such as sodium silicate) foam. Since the foam contains a noncombustible material or a flame retardant, the deposit surface is covered with a noncombustible solid. Thereby, supply of air for combustion of combustible deposits from above is suppressed, and in addition, flammable combustion at the time of combustion can be prevented, and spread of fire to the surroundings can be suppressed.

It is a longitudinal section showing a 1st embodiment of this invention. It is a longitudinal cross-sectional view which shows 2nd Embodiment of this invention. It is a longitudinal cross-sectional view which shows 3rd Embodiment of this invention. It is a longitudinal cross-sectional view which shows 4th Embodiment of this invention.

  A first embodiment of the present invention will be described with reference to FIG. Combustible deposits 5 are accommodated in a combustible deposit site surrounded by a fire-resistant peripheral wall 1, for example, in the pit 3. The combustible deposit 5 includes a plurality of combustible deposits 5 a in the pit 3. It is thrown in and deposited. An ignition source 7 exists inside the combustible deposit 5. An injection nozzle 9 is disposed in the vicinity of the pit 3, and the injection nozzle 9 is connected to a solution tank 10.

  The solution tank 10 contains a seal layer forming agent (an example of a seal agent). The seal layer forming agent includes a flame spread prevention gel (an example of a gel), an incombustible material or a flame retardant, and silicic acid. Sodium (an example of a water-soluble inorganic substance). As the fire spread prevention gel, for example, a substance containing bentonite or the like and having high viscosity, swelling property and thixotropic property is used, and as a non-combustible material or a flame retardant, for example, perlite (expanded pearlite), vermiculite (Expanded meteorite) is used. The water-soluble inorganic substance is not limited to sodium silicate, and may be other water-soluble inorganic substances such as sodium chloride.

  Next, the operation of this embodiment will be described. When a fire occurs in the pit 3, the worker 11 grasps the injection nozzle 9 and injects (radiates) the seal layer forming agent toward the combustible deposit 5 in the pit 3. Then, the seal layer forming agent adheres evenly to the entire surface while moving on the surface of the combustible deposit 5 without penetrating into the combustible deposit 5, thereby forming the barrier seal layer 13. Since the sealing layer forming agent has thixotropic properties, the viscosity decreases and fluidizes when released, and is smoothly discharged. However, after reaching the combustible deposit 5, the viscosity is recovered and solidified.

  The seal layer forming agent (fire spread prevention gel) of the barrier seal layer 13 is heated by the high temperature combustible material 5a, the moisture of the gel evaporates, and when further heated, sodium silicate foams. Since the foam contains an incombustible material or a flame retardant, the entire surface of the combustible deposit 5 is covered with an incombustible solid. For this reason, the supply of air A for combustion of the combustible deposit 5 from above is controlled (blocked), and flame combustion at the time of combustion is prevented, thereby suppressing the spread of fire. Moreover, since the shielding seal layer 13 is a non-combustible solid, the effect can be continued for a long time. Thereby, a fire, especially a deep layer fire can be suppressed and extinguished.

  It should be noted that even if only the flame spread prevention gel and sodium silicate are used as the seal layer forming agent, the solid volume is not as high as when a non-combustible material or a flame retardant is added, but the entire surface of the combustible deposit 5 is blocked. It can be covered with a sealing layer 13. In addition, as the seal layer forming agent, even if only the flame spread prevention gel and the non-combustible material or the flame retardant are used, when the gel evaporates, only the non-combustible material or the flame retardant is used. However, the entire surface of the combustible deposit 5 can be covered with the shielding seal layer 13.

  Furthermore, even if only a sodium silicate solution and a non-combustible material or a flame retardant are used, the fluidity cannot be obtained as much as when a flame spread prevention gel is added. However, the entire surface of the combustible deposit 5 can be covered with the shielding seal layer 13.

A second embodiment of the present invention will be described with reference to FIG. 2. The same reference numerals as those in FIG. 1 have the same names and functions. Differences between the present embodiment and the first embodiment are as follows.
(1) The nozzle housing chamber 17 partitioned by the placement net 15 is provided at the bottom 3 a of the pit 3. The placement net 15 prevents the spray nozzle 19 from coming into contact with the combustible material 5a.

(2) An upward spray nozzle 19 is disposed in the nozzle housing chamber 17 at a predetermined interval along the bottom 3a.
(3) The spray nozzle 19 is connected to a steam supply source (not shown) such as a boiler chamber.

  In the present embodiment, when a fire in the pit 3 occurs, the blocking seal layer 13 is formed in the same manner as in the above embodiment to cover the entire surface of the combustible deposit 5 and block the air A, and the spray nozzle 19 From the bottom layer side of the combustible deposit 5, the steam S is sent. Then, the water vapor S rises while sewing the gap between the combustible materials 5a and adheres to the combustible material 5a. Therefore, the cooling / suffocation effect due to the accumulation of the water vapor S in the combustible sediment 5 can be exhibited. That is, the water vapor S has a suffocation effect by filling the gaps between the combustible deposits 5 (combustible material 5a) and a cooling effect by adhering to the combustible sediments 5 (combustible material 5a) of less than 100 ° C. and dew condensation. It can be demonstrated. Thereby, a fire, especially a deep layer fire can be suppressed and extinguished.

A third embodiment of the present invention will be described with reference to FIG. 3. The same reference numerals as those in FIG. 1 have the same names and functions. Differences between the present embodiment and the first embodiment are as follows.
(1) The nozzle housing chamber 17 partitioned by the placement net 15 is provided at the bottom 3 a of the pit 3. The placement net 15 prevents the gas nozzle 20 from coming into contact with the combustible material 5a.
(2) Upward gas nozzles 20 are disposed in the nozzle housing chamber 17 at predetermined intervals along the bottom 3a.

(3) The gas nozzle 20 is connected to a gas tank (not shown). This gas tank is filled with an inert gas heavier than air (an example of a fire extinguishing gas), for example, an inert gas such as CO ₂ or N ₂ .
(4) The seal layer forming agent is released from the sprinkler head 21 disposed on the ceiling surface or the like.

  In this embodiment, when a fire occurs in the pit 3, the shut-off seal layer 13 is formed in the manner of the above-described embodiment to cover the entire surface of the combustible deposit 5 and shut off the air A, and from the gas nozzle 20. The inert gas G is injected, and the inert gas G is sent from the bottom layer side of the combustible deposit 5. Then, the inert gas G rises while being deposited while sewing the gaps between the combustible materials 5 a, so that the suffocation effect due to the accumulation of the inert gas G inside the combustible sediment 5 can be enhanced. Thereby, a fire, especially a deep layer fire can be suppressed and extinguished.

  A fourth embodiment of the present invention will be described with reference to FIG. 4. The same reference numerals as those in FIG. 3 have the same names and functions. The difference between the present embodiment and the third embodiment is that the gas nozzle 23 is disposed not only on the bottom 3a of the pit 3 but also on the peripheral wall 1 on the bottom 3a side. Thereby, the same effects as those of the third embodiment can be obtained. The gas nozzle 23 is not limited to the peripheral wall 1 on the bottom 3a side, and may be disposed on the peripheral wall 1 (the peripheral wall 1 on which the combustible material 5a is deposited) on the upper side. In this case, the nozzle housing chamber may also be provided on the side surface of the peripheral wall 1.

  In the third and fourth embodiments, as an example of the fire extinguishing gas, an inert gas heavier than air has been described, but other fire extinguishing gas such as a halogenated gas may be used. Moreover, since the whole surface of the combustible deposit 5 is covered with the shielding seal layer 13, the fire extinguishing gas is not necessarily heavier than air.

  In all the above-described embodiments, it has been described that the seal layer forming agent is discharged from the spray nozzle 9 or the sprinkler head 21, but any one of the spray nozzle 9 or the sprinkler head 21 and other discharge means, or any one of them. The seal layer forming agent may be released from the combination.

1 peripheral wall, 3 pits, 5 combustible deposit, 5a combustible material, 9 injection nozzle, 13 barrier seal layer, 19 spray nozzle, 20 gas nozzle, 23 gas nozzle, G gas, S water vapor

Claims (4)

A method of suppressing a fire in a combustible depository surrounded by a surrounding wall,
A sealing agent containing gel, a noncombustible material or a flame retardant, and a water-soluble inorganic substance is released from above the flammable deposit in the flammable deposit, thereby forming a barrier seal layer covering the entire surface of the flammable deposit. A fire suppression method characterized by:   The fire suppression method according to claim 1, wherein the gel is a thixotropic substance.   The fire suppression method according to claim 1 or 2, wherein water vapor is jetted from a bottom side of the combustible deposit site.   The fire suppression method according to claim 1 or 2, wherein a fire extinguishing gas is radiated from the bottom side of the combustible deposit site.

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