RU2278711C1 - Fire suppression method system - Google Patents

Abstract

FIELD: fire fighting, particularly to extinguish fire in large volatile flammable liquid storage facilities under low ambient temperatures in northern zones.

SUBSTANCE: method involves delivering fire-extinguishing powder via pipeline to fire site so that fire-extinguishing powder is fluidized and aerated along the full pipeline length. Fire-extinguishing system comprises fire-extinguishing powder supply pipeline installed in potential fire initiation zone, accumulation vessels for fire-extinguishing powder, compressed gas source and alarm means. The supply pipeline has gas-permeable longitudinal partition, which divides the pipeline into low-pressure and high-pressure cavities. The pipeline is provided with outlet valves and is connected with compressed gas source through accumulation vessels. Alarm means are made as infrared sensors and are communicated with control electronic apparatus. Each outlet valve is provided with electric drive connected with control electronic apparatus.

EFFECT: provision of fire extinguishing in the cases, in which water and fire-extinguishing foam usage is impossible, increased reliability and safety of fire suppression under low temperatures, reduced fire-extinguishing system response time and decreased maintenance costs.

7 cl, 4 dwg

Description

The invention relates to a fire extinguishing technique for mainly large objects of storage of flammable liquids and combustible materials at low ambient temperatures in northern latitudes. It may find application in the elimination of fires with restrictions on the use of water and fire extinguishing foam.

In the north, fire extinguishing systems using water and foam are not always reliable and, as a rule, not technologically advanced, require special energy-intensive measures to maintain water and foam in technological readiness both during storage and during transportation. Known powder fire extinguishing agents are not effective enough, and in some cases they themselves can become a source of secondary fire, because use explosive energy when fired. An optimal solution would be a fire extinguishing method and system based on the use of a fire extinguishing powder with high adaptability, speed and safety of use.

A known method of pulsed atomization of a substance by ejecting it from a barrel into a gaseous medium with explosive speed using the energy of the gas generated by the combustion of a powder charge, which consists in the fact that a metered amount of the atomized substance, previously enclosed in an airtight container, is placed in the barrel channel and the container by gas pressure, pushing it into the environment, characterized in that said sealed container is made elastic with the possibility of its destruction due to NOSTA pressure within the container and the ambient pressure, container ejection is performed gradual increase of the gas pressure in the barrel and its contents is carried out at sputtering destruction container as it leaves the barrel / Patent RU №2182027, 2002 g. /.

The known method is not sufficiently operational when applied, not sufficiently productive and safe, it requires the presence of a person, only with great limitations it can be used in automatic mode.

A powder fire extinguishing device is known comprising a cylindrical body filled with a fire extinguishing powder with a bottom, a pyrotechnic charge and an igniter assembly located in the bottom and separated from the powder by a piston, and a cover sealing the housing on the open end side, characterized in that the piston has perforations, centers which are located radially symmetrically, uniformly on circles concentric with respect to the axis of the piston, and the total area of the perforations is 3.5-25.0% pl show mercy to the piston / Patent RU №2085235, 1997 /.

The known device is also not sufficiently operational in use, not sufficiently productive and safe, requires the obligatory presence of a person, hardly applicable for use in automatic mode.

A known method of pulsed atomization of a liquid or powder by ejecting a charge of a liquid or powder with explosive speed into a gaseous medium under the impact of a gas stream with high kinetic energy, characterized in that a powder and / or pyrotechnic charge with energy is used as a source of gas with high kinetic energy combustion from 2 to 6 MJ / kg with the ratio of the charge mass of the sprayed liquid or powder to the mass of the powder and / or pyrotechnic charge from 500 to 3000 and the charge density of the powder and / or a pyrotechnic charge of at least 0.6 kg / l and the ejection of a liquid or powder charge is carried out by directly influencing the gas flow on the liquid or powder charge / Patent RU No. 2127622, 1999 /.

The known method is not convenient enough and reliable, not productive and safe enough, it is limited applicable in automatic mode.

A device is known for pulsed atomization of a liquid or powder in a gaseous medium, including a barrel for ejecting a charge of a sprayed substance with an outlet at one end and an inlet for a gas flow with high kinetic energy at the other end, characterized in that it contains a combustion chamber coaxially with the barrel powder and / or pyrotechnic charge and means for initiating the combustion of the charge, while the combustion chamber is rigidly connected to the barrel so that its inlet coincides with the outlet the aperture of the combustion chamber / Patent RU №2127622, 1999 /.

The known device does not have sufficient performance and safety, is practically intended for a single shot, requires recharging during a fire, is not convenient and reliable enough to use, it is limited applicable in automatic mode.

The closest is a fire extinguishing method, which includes the complex effect of an inhibitory aerosol and extinguishing agent on the combustion site, and the supply of the inhibiting aerosol and extinguishing agent is carried out simultaneously from a single device or devices in the form of a stream of extinguishing agent sprayed in a cooled inhibiting aerosol, while the inhibiting aerosol is obtained as a result combustion aerosol-forming composition / Patent RU No. 2118551, 1998 /.

The known method is not sufficiently productive and safe, not technologically advanced and reliable, it is limited applicable in automatic mode.

The closest is a fire extinguishing system containing a fire detection means, at least two different types of fire extinguishing devices that are switched on simultaneously or sequentially, means for their initiation, characterized in that an aerosol generator or aerosol generators of any type with aerosol cooling means are used as one fire extinguishing device and as another or others, an aerosol-powder generator or aerosol-powder generators with cooling an aerosol emitter and / or an aerosol-liquid generator or aerosol-liquid generators with the possibility of initiating a fire extinguishing device automatically by a signal from the control panel or from a sensor, for example, a thermal, smoke, spectral, or fire-retardant cord, or manually by switching on a toggle switch or other starting device , or their combination, and the means for initiating fire extinguishing devices are additionally interconnected by a fire-conduit or bikford cord, at the same time, different types of fire extinguishing devices solutions are fixed at various points of the protected object, while the aerosol-powder and aerosol-liquid generators are directed by means for extinguishing the extinguishing agent directly onto fire hazardous materials that can accumulate thermal energy / Patent RU No. 2111551, 1998 /.

The known device is excessively inertial, does not have sufficient performance and safety, is not convenient and reliable enough to use, it is limited to be applied at low temperatures in automatic mode.

The objective of the invention is to increase the reliability and safety of fire extinguishing at low temperatures, reducing the inertia of the fire extinguishing system and the cost of operation. The problem is solved in that in a method for eliminating a fire, including supplying a fire extinguishing powder to a combustion zone through a pipeline, according to the solution, the powder is supplied in a fluidized state with aeration along the length of the pipeline; The problem is also solved by the fact that in the system for implementing the method, which includes a supply pipe installed in a potential fire zone, storage tanks for extinguishing powder, a compressed gas source and signal devices, according to the solution, the supply pipe is made with a gas-permeable longitudinal partition dividing the latter into high and low pressure, while the pipeline is equipped with exhaust valves, connected to a source of compressed gas through storage tanks, and the signal devices are made in the form of infrared sensors and connected to a control electronic device, each exhaust valve is equipped with an electric actuator connected to the control electronic device, infrared sensors are installed in the area of each exhaust valve on the supply pipe, the source of compressed gas is made in the form of a receiver with the ability to pump gas from the compressor, each the storage tank is made with a gas-permeable partition dividing the latter into high and low pressure zones, with each zone connected to a res Verom separate conduits equipped with a solenoid-pressure reducers connected with a control electronic device, each storage capacitance is further provided with an outlet nozzle with a movable sealing lid associated electrically connected with a control electronic device. Distinctive features are:

- the powder is fed in a fluidized state (which allows you to move the powder as a liquid through the pipeline without heating the latter at any negative ambient temperatures and improves the processability);

- the powder is fed with aeration along the length of the pipeline (which ensures the transportation of powder to any point along the length of the pipeline over the length of the entire fire protection facility);

- the supply pipeline is made with a gas-permeable longitudinal partition dividing the latter into zones of high and low pressure (which provides fluidization of the powder in the pipeline and the possibility of transportation in it as an anti-freezing and non-thickening liquid);

- the pipeline is equipped with exhaust valves, connected to a source of compressed gas through storage tanks (which ensures the supply of the required amount of powder to any point of the object with high speed);

- the signal devices are made in the form of infrared sensors and are connected to a control electronic device (which makes it possible to quickly determine the fire moment and give commands to the chain of actuators);

- each exhaust valve is equipped with an electric actuator connected to a control electronic device (which, in addition to increasing the speed of turning valves on, provides the ability to control the volume and targeting of the powder supply);

- infrared sensors are installed in the area of each exhaust valve on the supply pipe (which allows you to accurately determine the coordinates of the fire and the direction of supply of the extinguishing powder, to increase the reliability of the system);

- the source of compressed gas is made in the form of a receiver with the possibility of pumping gas from the compressor (ensuring high flow rates and the speed of the extinguishing powder with a large supply of transporting agent);

- each storage tank is made with a gas-permeable partition separating the latter into high and low pressure zones, with each zone connected to the receiver by separate pipelines equipped with pressure reducers with an electro-pneumatic valve connected to the control electronic device (ensuring the fluidized state of the powder in the storage tank, and consequently, constant readiness for transportation to the place of ignition at low temperatures, increasing the responsiveness of the system we and automation capabilities);

- each storage tank is equipped with an outlet pipe with a movable sealing cap connected to an electric drive connected to a control electronic device (increasing the response time of the system and the possibility of automation, directing the supply of fire extinguishing powder, increasing the reliability of the response of the system). Thus, the claimed solution meets the criterion of "novelty."

Comparison of the proposed solutions with analogues did not allow them to identify signs that distinguish the claimed solution from the prototype, which allows us to conclude that its criterion of "inventive step".

The method is implemented as follows.

A 45 m long rectangular pipeline with a cross-sectional area of the conveying channel of 100 cm ² and 50 cm ^{2 of the} aeration channel at an overpressure of 0.8-0.9 kg / cm ² and 1.5-1.8 kg / cm ² , respectively initiated by the receiver, and a height difference of 5.5 m is supplied to the combustion zone in a pseudo-fluidized state fire extinguishing powder ABCE-ISTO-1. At the exit, a stable conical-shaped jet is obtained with a flow rate of 18-24 m / s and a capacity of 25-32 kg / s of fire extinguishing powder, which ensures the elimination of the source of ignition of oil products with an area of 25 m ² .

The system for implementing the method is illustrated by drawings, in which Fig. 1 shows a system in a side view in the form of a complex section along AA, in Fig. 2 is a top view, Fig. 3 is an enlarged fragment of a section of the supply pipe, Fig. 4 is an enlarged fragment section of storage capacity. The system contains a supply pipe 1 with a gas-permeable longitudinal partition 2, zones of high 3 and low 4 pressure, exhaust valves 5 with locking electric actuators 6, infrared sensors 7, storage tanks 8, 9 with gas-permeable partitions 10 and zones of high 11 and low 12 pressure, outlet nozzles 13, 14 with movable sealing caps 15, 16, connected with electric drives 17, 18, pipelines 19, 20, equipped with pressure reducers 21, 22, electro-pneumatic valves 23, 24, receiver 25, compressor 26, electronic control device TVO - a computer (not shown).

The system operates as follows.

In the initial state, a high pressure is maintained in the receiver 25 due to the compressor 26, and the required amount of extinguishing powder is contained in the storage tanks 8, 9.

When the ignition starts, the signal from the sensors 7 is fed to a control electronic device - a computer, from which commands to the electro-pneumatic valves 23, 24 follow, after which, through pipelines 19, 20, compressed air is supplied under pressure reducers 21, 22 under a pressure of 1.5-1, 8 kg / cm ² in the high pressure zone 11 and under pressure of 0.8-0.9 kg / cm ² in the low pressure zone 12 of the storage tanks 8, 9. From the high pressure zones of the storage tanks, compressed air enters the high pressure zone 3 of the supply pipeline 1, and along the entire length of the gas pipeline of the flowing longitudinal partition 2 and over the entire area of the gas-permeable partitions 10, the process of air outflow is initiated with the creation of a fluidized mass of fire extinguishing powder, first in the storage tanks 8, 9, and then in the supply pipe 1. The fluidized powder acquires properties close to fluidity, and comes from the low-flow zone pressure of 12 storage tanks 8, 9 to the low pressure zone of the supply pipe 1. Simultaneously with the start of the system for eliminating the fire at the signal of the control electronic device - computer - a command is issued to the locking electric actuators 6 of the exhaust valves 5 with the opening of the latter and the expiration of the fluidized mass of the extinguishing powder in the ignition zone. At the same time, all exhaust valves can be opened, as well as one or two. The opening of the valves is determined by the number and intensity of the signals received by the electronic control device - a computer - from sensors 7 located next to the exhaust valves. The program can include various valve opening sequences that ensure reliable elimination of fire and the simultaneous use of both storage tanks 8, 9, and the use of one of the tanks. In technological readiness, the system is supported by periodic pumping of powder from one storage tank to another with closed exhaust valves, open outlet pipe 13 and closed 14 (or vice versa). Accordingly, the signal from the control device is supplied to the electric drive 17 connected to the movable sealing cover 15, which ensures the release of transporting air and the deposition of extinguishing powder in the storage tank. After the completion of periodic pumping in the supply pipe 1 on the gas-permeable longitudinal partition 2, there is always a layer of fire-extinguishing powder, sufficient for instant readiness of the system for operation when compressed air is supplied to the high-pressure zone 3.

The fire extinguishing method and the system for implementing the method provide increased reliability and safety of fire extinguishing at low temperatures, reducing the inertia of the fire extinguishing system and the cost of operation.

Claims (7)

1. A method of eliminating a fire, comprising supplying a fire extinguishing powder to a combustion zone through a pipeline, characterized in that the powder is supplied in a fluidized state with aeration along the length of the pipeline. 2. A system for implementing the method, including a supply pipe installed in a potential fire zone, storage tanks for extinguishing powder, a compressed gas source and signal devices, characterized in that the supply pipe is made with a gas-permeable longitudinal partition dividing the latter into high and low pressure zones, the pipeline is equipped with exhaust valves, connected to a source of compressed gas through storage tanks, and the signal devices are made in the form of infrared sensors forged and commutated with a control electronic device. 3. The system according to claim 2, characterized in that each exhaust valve is equipped with an electric actuator connected to a control electronic device. 4. The system according to claim 2, characterized in that the infrared sensors are installed in the area of each exhaust valve on the supply pipe. 5. The system according to claim 2, characterized in that the source of compressed gas is made in the form of a receiver with the ability to pump gas from the compressor. 6. The system according to claim 2, characterized in that each storage tank is made with a gas-permeable partition separating the latter into high and low pressure zones, each zone being connected to the receiver by separate pipelines equipped with pressure reducers and an electro-pneumatic valve connected to an electronic control device . 7. The system according to claim 6, characterized in that each storage tank is equipped with an exhaust pipe with a movable sealing cover associated with an electric drive connected to a control electronic device.

Images