RU2193906C2 - Fire-extinguishing method and rocket-type fire-extinguishers for effectuating method - Google Patents

Abstract

FIELD: fire-fighting. SUBSTANCE: method involves using rocket-type fire-extinguishers as means for transportation of fire-suppressing devices to fire-fighting zone; starting rocket-type fire-extinguishers by means of fire discharge apparatus such as launcher mounted on helicopter; providing successive discharges of air knock wave and rocket-exhaust cloud of fire-extinguishing substance above fire zone at predetermined time interval by rockets, whose fire-suppressing devices adapted for first discharge in a volley are filled with explosive substance and for second discharge in a volley with retarding dispersion; setting number of rockets comprising one or other substance depending on type and area of fire zone. Rocket-type fire-extinguisher with fire-extinguishing retarding dispersion has engine equipped with combustion chamber and connected to container, which is charged with fire-extinguishing retarding dispersion and provided with nozzle openings formed in bottom and cylindrical parts, and is further equipped with air intake device, pyrotechnic cartridge, control signal receiver, cut of Bickford fuse, container and casing movably mounted on container, and obturator detachably positioned on casing. Openings are made in cylindrical surfaces of container and related casing. Rocket-type fire-extinguisher for suppressing fire with air knock wave has engine provided with combustion chamber and connected with casing charged with explosive substance. Casing incorporates control signal receiver connected to inertia detonator, and length of Bickford fuse connected to bottom part of combustion chamber and to inertia detonator. Method and extinguisher are used for suppressing forest and steppe fires occurring in difficult-to-reach places (steep mountains, impassable forest, high temperature, dangerously explosive places). EFFECT: increased efficiency and improved precision of action of explosive energy and fire-suppressive substances at safe distance from fire zone. 14 cl, 3 dwg

Description

 The invention relates to environmental ecology, to fire extinguishing methods and techniques based on aviation delivery vehicles, for example helicopters, and can be used to extinguish forest, steppe and other fires, as well as fires that arise in hard-to-reach places (steep mountains, impenetrable forest, high temperature, explosion hazard).

 Known methods of extinguishing forest, steppe and other fires with water from tanks, fire extinguishers with chemicals, using aviation (Guidelines for the detection and extinguishing of forest fires. M., 1995, S. 35-43).

 The use of aviation fire extinguishing means, namely tanker aircraft and helicopters with pouring devices, is not always effective, because with their help it is difficult to ensure sufficient accuracy of the water supply to the combustion zone, and in addition, part of the water evaporates and is carried away by the ascending heat flow.

 A known method of extinguishing a fire, in which fire bombs filled with means designed for fire extinguishing, is hung on garlands that are located between two or three helicopters, and dumped into the fire extinguishing zone. The bomb is equipped with a blade screw connected to a worm screw. The housing is made of two halves, for the disclosure of which the said screw screw is intended (RU 2068286, C1, 10.27.1996).

 The disadvantage of this method is its bulkiness, unproductive use of aircraft, the low reliability of the disclosure of the bomb body, the inefficiency of spraying a fire extinguishing agent over the area of the fire.

A known method of extinguishing using existing aircraft and aviation equipment, which consists in the fact that the extinguishing fluid is pre-cooled to a negative temperature of -56.5 < ^o C <0 and dumped together with the tank into the fire. Cooling of the extinguishing liquid is carried out in fire extinguisher bombs on the suspension by blowing with a stream of frosty air during a flight at altitudes above 2500 m. Crushing of the extinguishing liquid and dispersal of the droplets are carried out in the fire center by a bomb explosion (SU 1712245, A1, 03.01.1990).

 The disadvantage of this method is the long time for cooling the liquid to a negative temperature, the need for the simultaneous use of a large number of aircraft, high consumption of aviation fuel.

 A known method of extinguishing forest, steppe and other fires by simultaneous volley of several fire extinguisher barrels from an impulse platform suspended, for example, from a helicopter (RU 2146545, C1, 03/20/2000).

 The disadvantage of this method is the need for transportation to the fire zone of a bulky impulse installation on a suspension cable to a helicopter, a long reload time in stationary conditions.

 A known method of localization and extinguishing forest fires using composite systems containing elements with an explosive and extinguishing agent, which are mobile delivered to the fire front by ground or air based systems, are discharged into the fire and initiate a sequential blasting of both systems and the forest canopy the elements themselves in time and over the entire height of the forest (SU 1789232, A1, 01/23/1993).

 The disadvantage of this method is its low efficiency, since it allows in certain situations re-ignition in certain areas, and further development of the fire is possible. This is due to the uncertainty of the sequence and concentration of the impact of the blast wave and extinguishing agent in the fire.

 A known method of localization and / or extinguishing fires, designed to deal with large-scale and powerful fires that occur in hard-to-reach places, consisting in combining exposure to a fire source with an air shock wave and a dispersed cloud of extinguishing agent created by fire suppression devices filled with explosive and extinguishing substances, in the definition of the extinguishing sites, in the implementation of the approach of the means of delivery of the fire suppression device with the fire of the explosive and the formation of dispersed cloud by a sensor signal, pre-configured to a given parameter (RU 2111032, C1, 05.20.1998). This method is adopted as a prototype.

 The disadvantages of the known method adopted as a prototype are the impossibility of differentiated effects on the fire site by the blast wave and extinguishing agent, depending on the type of fire, which reduces the efficiency of the method, as well as the bulkiness of the launcher and the complexity of its transportation on the suspension, especially take-off and landing of a helicopter with a suspended container, the difficulty of processing large areas of fire in a fairly short time.

 A known fire extinguisher containing a rocket engine and a container filled with extinguishing agent (FR 2603492, A1, 03/11/1998). This device is taken as a prototype.

 A disadvantage of the known device adopted for the prototype is the low efficiency of its use due to the lack of control elements for the dispersion of dispersed extinguishing agent in the container structure. Another disadvantage of the known device adopted for the prototype is the lack of a system for detonating an explosive charge when placed in a rocket container.

 The main task to be solved by the claimed method of extinguishing a fire and a fire extinguisher for its implementation is to increase the efficiency of fire suppressants delivered to the fire extinguishing zone by concentrating, selectively and sequentially exposing the fire source to an air shock wave and extinguishing dispersed refluxing substance in depending on the specific situation in the fire zone, as well as by increasing the power of fire suppressants and the accuracy of their impact by both sintering the optimal ratio of the mass of the extinguishing agent to the total mass of the delivery vehicle, and from a point that is safe from the fire-fighting zone.

 The single technical result achieved in the implementation of the claimed group of inventions is to increase the efficiency of suppressing fire in large spaces and with difficult access to the fire by the technology of separate-sequential exposure, depending on the area and type of fire.

 The specified technical result is achieved by the fact that in the known method of extinguishing fires, which consists in combining exposure to the fire with an air shock wave and a dispersed cloud of extinguishing agent created by fire suppression devices filled with explosive and extinguishing agents, in determining the extinguishing sites, in the implementation of the approach of the delivery vehicle fire suppression device with a fire source of explosive explosions and the formation of a dispersed cloud by a sensor signal, previously us swarm to a predetermined parameter, according to the proposed technical solution, as means of delivery of fire suppression devices to the fire extinguishing zone, rockets are used that are accurately launched using helicopter launchers, while the creation of an air shock wave and dispersed cloud of extinguishing agent above the fire is carried out sequentially with a predetermined time interval volleys of rockets, fire suppression devices of which for the first volley are filled with explosive, and for the second volley - phlegmatizing dispersed fire extinguishing agent, and the number of missiles with a particular substance is set depending on the type and area of the fire; that the fire suppression device is delivered to the fire extinguishing zone by accelerating the rocket in the active section of the trajectory to a speed that ensures its inertial movement to a given target; that the action of the fire suppression device is initiated by the missile guidance system through the control signal receiver; that the action of the fire suppression device is initiated by the time controller in the inertial mode of the missile flight; that the dispersion of a dispersed extinguishing agent over a fire is carried out under the influence of the high-speed pressure of the oncoming air mass.

 The specified technical result is achieved by the fact that in the known fire extinguisher containing a rocket engine and a container filled with a fire extinguishing agent, the container is filled with dispersed phlegmatizing fire retardant and made with an air intake and nozzle openings for dispersing the extinguishing agent, while a casing with holes is movably mounted on the container having the ability to close nozzle openings, and a cowl is mounted on the casing, which is discharged from the air intake by a casing, shifted along the length l container using the actuator at the time of opening of the nozzle holes according to the sensor signal setting the moment of opening of the container; that the job of opening the container contains a time relay; that the job opening moment of the container contains a signal receiver from the guidance system; that a pyro cartridge connected to a time relay and a signal receiver from the missile guidance system was used as the actuator for opening the container; that on the cylindrical surfaces of the casing and the container, holes are additionally made for dispersing the extinguishing agent with a step equal to the displacement of the casing when the container is opened; that the sensor sets the moment of opening of the container is connected to the combustion chamber of the rocket engine and initiates a signal with the end of the combustion of fuel; that a Bikford cord of a given length is used as a time relay, connecting the combustion chamber of a rocket engine with a squib; that the rocket engine is equipped with a fuel capacity sufficient to accelerate the rocket to a speed that ensures that it reaches a given target in an inertial flight.

 The specified technical result is achieved by the fact that in a known fire extinguisher containing a housing and a rocket engine, according to the proposed technical solution, it comprises a signal receiver from the missile guidance system and a time relay, and the housing is filled with explosive, while the signal receiver and time relay are associated with an inertial detonator for detonating an explosive, initiating an explosion to create an air shock wave.

 The analysis of the prior art by the applicant has made it possible to establish that there are no analogues that are characterized by sets of features identical to all the features of the claimed method of extinguishing a fire and a fire extinguisher. Therefore, each of the claimed technical solutions meets the condition of patentability "novelty."

 The search results for known solutions in this technical field in order to identify signs that match the distinctive features of the prototype of each of the proposed technical solutions showed that they do not follow explicitly from the prior art. From the prior art determined by the applicant, the influence of the transformations provided for by the essential features of each of the claimed technical solutions on the achievement of the specified technical result is not revealed. Therefore, each of the claimed technical solutions meets the condition of patentability "inventive step".

 In the present application for the grant of a patent, the requirement of unity of invention is met, since the method and devices are designed to extinguish a fire. The claimed technical solutions solve the same problem: creating a fire extinguishing technology and developing a fire extinguisher design that can effectively deal with fires in remote places of their occurrence.

 In FIG. 1 shows a fire extinguisher equipped with a particulate extinguishing agent; figure 2 is the same in the open position; figure 3 - fire extinguisher with an explosive charge.

 The method of extinguishing a fire is as follows. When a fire message arrives, the helicopter's multiple launch rocket launchers are charged with fire extinguishers, while a supply of missiles is loaded on board for subsequent recharging, and the helicopter is sent to the fire extinguishing zone. By preliminary examination of the fire from the helicopter, the type of fire and the fire extinguishing area to be extinguished are estimated. Based on the assessment of the state of the fire zone, fire extinguishing sites and the number of missiles with explosive for preliminary extinguishing a fire by a shock wave and the number of missiles with dispersed extinguishing agent to form a phlegmatizing cloud of an extinguishing composition are determined. Charges of explosive and dispersed extinguishing agent are delivered to the fire zone separately-sequentially in fire extinguisher rockets, which are fired from a helicopter's multiple launch rocket launcher. From a position at a distance corresponding to the range of missiles, aiming using guiding means produce successive salvos of missiles, first filled with explosive, and then, with an interval in time, phlegmatizing dispersed substance. During the first volley of rockets under the influence of an air shock wave, the flame breaks down, especially when extinguishing a forest, when the fire is lost in light-burning materials - leaves, needles and other trees break off from the trees with a shock wave. Subsequent spraying of dispersed phlegmatizing composition with the help of fire extinguishers of the second volley suppresses the focus fires. In the presence of residual fire sources, additional volleys are made until the fire is completely suppressed. To reload rocket launchers, they land the helicopter in a place safe from the fire zone and use the reserve of missiles taken on board the helicopter.

 A fire extinguisher rocket for implementing a method of extinguishing a fire with a dispersed phlegmatizing fire extinguishing composition consists of a rocket engine 1, including a combustion chamber 2 with rocket fuel, connected to a container 3 filled with dispersed fire extinguishing agent 4 and having nozzle openings 5 in the bottom and 6 in its cylindrical parts, the air intake 7 on the container 3, the squib 8, the receiver 9 of the control signal, a segment of the Bikford cord 10, the casing 11 with holes 12 on a cylindrical surface, movably mounted on and the container 3, fairing 13 mounted on the casing 11 (figure 1). In the open position of the fire extinguisher, the casing 11 is shifted relative to the container 3, as a result of which the nozzle holes 5 on the bottom of the container 3 are open, and the holes 12 on the casing 11 are aligned with the holes 6 on the container 3 and form nozzle holes on the lateral cylindrical part of the fire extinguisher for the release of dispersed extinguishing agent over the fire (Fig.2).

 A fire extinguisher for carrying out a method of extinguishing a fire by an air shock wave consists of a rocket engine 1, including a combustion chamber 2 with rocket fuel, connected to a housing 14 filled with explosive 15. In the housing 14 there is a control signal receiver 9 connected to an inertial detonator 16, and a segment of the Bickford cord 10 connecting the cavity of the combustion chamber 2 in its bottom with an inertial detonator 16 (figure 3).

 A fire extinguisher with a dispersed extinguishing agent operates as follows. After starting engine 1, a fire extinguisher flies out of the helicopter launcher and accelerates due to its own rocket fuel to a speed that ensures its inertia to a given target. At the end of the process of burning fuel in the combustion chamber 2, the Bickford cord 10 is ignited, one end of which is located in the bottom of the chamber, and the other is connected to the squib 8.

 The burning time of the Bikford cord corresponds to the time of the rocket's approach to the target in the inertial mode. Upon reaching fire from the Bikford cord of the squib 8, the latter is undermined, as a result of which, under the pressure of the gases acting on the fairing 13, the casing 11 is moved relative to the container 3 until the bottom nozzle holes 5 open and the holes 6 and 12 are aligned on the cylindrical surfaces of the casing 11 and container 3 Thus, the fairing 13 is reset, freeing the air intake 7 of the container 3. Undermining the squib 8 can be performed or duplicated by the receiver 9 of the control signal from the missile guidance system from the cab us helicopter. After dropping the fairing 13, the air intake 7 on the container 3 opens and the oncoming air mass creates pressure on the dispersed extinguishing agent in the container 3 on the area of the air intake 7, and the air velocity along the cylindrical surface creates a vacuum, as a result of which the dispersed extinguishing agent 4 is blown out of the container 3, creating dispersed fire extinguishing cloud.

 The fire extinguisher with an explosive charge works as follows. After starting the engine, the rocket accelerates to the speed provided by the combustion of fuel from rocket engine 1. Next, the rocket continues to move by inertia. At the end of the fuel combustion process, the Bickford cord 10 is ignited, the end of which is located in the bottom of the combustion chamber 2. The combustion time of the Bickford cord 10 corresponds to the time of the rocket's approach to the target in the inertial mode.

 Upon reaching fire from the Bikford cord of the inertial detonator 16, an explosion of explosive 15 is initiated. The inertial detonator 16 can be initiated if necessary to change the time of the explosion or duplicated by the receiver 9 of the control signal from the missile guidance system. In the absence of impact from the Bikford cord 10 and the receiver 9 of the control signal, the inertial detonator 16 is triggered by an impact on an obstacle.

 The method allows for the universality of the use of fire suppression devices of two types in different combinations in forest, steppe, peat, oil and gas fires. The most effective missiles are caliber 80 mm with a range of 300-400 meters. The area of treatment of the fire source with one call of the helicopter is at least 56,000 square meters. For firefighting, military transport helicopters equipped with standard missile launchers are used.

Claims (14)

 1. The method of extinguishing fires, which consists in combining exposure to a fire site with an air shock wave and a dispersed cloud of extinguishing agent created by fire suppression devices filled with explosive and fire extinguishing substances, in determining the extinguishing sites, in the implementation of the approach of a fire suppression device delivery vehicle to a fire center for exploding substance and the formation of a dispersed cloud by a signal from a sensor pre-configured to a given parameter, characterized in that as Means of delivering fire suppression devices to the fire extinguishing zone use rockets that are aimed accurately using the helicopter launchers, while creating an air shock wave and dispersed cloud of extinguishing medium above the fire is carried out sequentially with a given time interval of volleys of rockets whose fire suppression devices for the first volley are filled with explosive , and for the second volley - phlegmatizing dispersed fire extinguishing agent, and the number of missiles with one or another substance Scale depending on the type and area of the fire.  2. The method of extinguishing a fire according to claim 1, characterized in that the fire suppression device is delivered to the fire extinguishing zone by accelerating the rocket in the active section of the trajectory to a speed that ensures its inertial movement to a given target.  3. The method of extinguishing a fire according to claim 1, characterized in that the action of the fire suppression device is initiated by a missile guidance system through a control signal receiver.  4. The method of extinguishing a fire according to claim 1, characterized in that the action of the fire suppression device is initiated by a time master in the inertial mode of the rocket’s flight.  5. The method of extinguishing a fire according to claim 1, characterized in that the dispersion of a dispersed extinguishing agent over the fire is carried out under the influence of the high-speed pressure of the oncoming air mass.  6. A fire extinguisher containing a rocket engine and a container filled with a fire extinguishing agent, characterized in that the container is filled with dispersed phlegmatizing fire retardant and made with an air intake and nozzle openings for dispersing the extinguishing agent, while a casing with holes is movably mounted on the container with the possibility closing nozzle openings, and a cowl is mounted on the casing, which is discharged from the air intake by a casing displaced along the container with the help of the actuator anizma at the opening of nozzle holes on the signal assignment torquer container opening.  7. The fire extinguisher according to claim 6, characterized in that the sensor for setting the moment of opening the container contains a timer.  8. The fire extinguisher according to claim 6, characterized in that the sensor for setting the moment of opening the container contains a signal receiver from the guidance system.  9. A fire extinguisher according to claim 6, characterized in that a pyro cartridge is used as the actuator for opening the container, connected to a time relay and a signal receiver from the missile guidance system.  10. The fire extinguisher according to claim 6, characterized in that on the cylindrical surfaces of the casing and the container, holes are additionally made for dispersing the extinguishing agent in increments equal to the displacement of the casing when the container is opened.  11. The fire extinguisher according to claim 6, characterized in that the sensor setting the moment of opening of the container is connected to the combustion chamber of the rocket engine and initiates a signal with the end of the combustion of fuel.  12. A fire extinguisher according to claim 6, characterized in that a Bicford cord of a given length is used as a time relay, connecting the combustion chamber of the rocket engine with a squib.  13. A fire extinguisher according to claim 6, characterized in that the rocket engine is equipped with a fuel capacity sufficient to accelerate the rocket to a speed that ensures that it reaches a given target in an inertial flight.  14. A fire extinguisher containing a housing and a rocket engine, characterized in that it comprises a signal receiver from the missile guidance system and a time relay, and the housing is filled with explosive, while the signal receiver and time relay are connected to an inertial detonator of explosive detonation, initiating explosion to create a shockwave.

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