RU2233681C1 - Method of fire-extinguishing agent delivery into container, fire-extinguishing plant and container for fire-extinguishing agent delivery - Google Patents

Abstract

FIELD: fire-extinguishing equipment, particularly for extinguishing difficult-to-extinguish fires from remote location.

SUBSTANCE: method involves feeding container from redirection chamber towards turbine by electrically-driven pusher; centering container by orientators; pushing container into vortex tube of turbine and exerting vortex flow influence upon container; rotating containers into barrel along with continuous movement thereof by moving flow in gas or liquid medium. Fire-extinguishing plant has fire-extinguishing device with barrel rotating in vertical and horizontal planes. Barrel in barrel frame is connected with turbine for container rotation and movement inside barrel. Vortex tube in turbine is connected with system of vortex forming channels. Turbine is joined with redirection means and with accumulator magazine. Containers are formed as cylindrical capsules and filled with fire-extinguishing agent. Containers also have igniters and explosion charges.

EFFECT: increased efficiency of fire and explosion suppression, universality of fire-extinguishing agents application, increased intensity of container delivery to fire site, increased volume and area covered with fire-extinguishing agent.

25 cl, 21 dwg

Description

The invention relates to the field of fire fighting equipment and can be used to extinguish various types of fires, effective localization of foci of ignition of industrial and civil facilities.

SUMMARY OF THE INVENTION When performing the method of containerized delivery of extinguishing agent, the delivery of extinguishing agent to the fire is carried out in contrast to existing methods in containers. To implement the method, a barrel-type fire extinguishing installation is proposed, which is a means of delivering containers with extinguishing agents. The extinguishing agent along with the mechanisms of formation of combustion and explosion is packaged in the internal cavity of the container body. At the fire extinguishing installation, the store magazine is filled with containers with extinguishing agent. The container from the store-drive is fed into the chamber cavity of the chambering device. With a mechanical pusher from the delivery chamber, the container is fed further in the direction of the turbine, the containers are centered by the orientators and pushed into the vortex flow tube, where they act under the vortex flow of gas or liquid under pressure on the container. In the barrel, the container is rotated and moved by a continuously moving stream in the working medium of gas or liquid. The driving force of the container in the inner cavity of the barrel of the fire extinguishing device is the vortex flow. But the working medium of the vortex flow is a fire extinguishing agent in addition to the main fire extinguishing substance in containers. During the movement of containers in the barrel, a distributed vortex flow is applied to the rear end part (rear wall) of the containers with the ability to control the speed of movement of containers in the barrel. The barrel type fire extinguishing installation for implementing the method has a barrel type fire extinguishing device with the ability to rotate the barrel in a vertical and horizontal plane. The internal cavity of the barrel is filled with containers with a fire extinguishing agent. The barrel in the receiver is connected to a turbine for rotating and moving containers inside the barrel. The turbine on the opposite side with respect to the barrel is connected to the device for dispensing the container from the cavity in the swirl flow pipe located in the central zone of the turbine casing. The pipe is connected to the vortex flow channel system. The turbine is made in two versions: open and closed type. In an open type turbine, the channel system is interfaced with the internal cavity of the vortex flow pipe and is brought directly to the central zone of the turbine casing. In a closed-type turbine, the internal cavity of the vortex flow pipe is isolated in the turbine housing from the channel system, and the turbine channel system is led to the end of the turbine directly to the inlet of the barrel and smoothly interfaced with the inner cavity of the inlet of the barrel. The channel system has two versions: with a centralized and distributed supply of gas or liquid. Containers that implement, using a barrel type fire extinguishing installation, a method for the container delivery of extinguishing agent, is made in the form of a box-shaped capsule, preferably a cylindrical one. Extinguishing agents and, if necessary, mechanisms for the formation of chemical reactions inside the container, the formation of combustion of fire extinguishing substances, or explosion are placed in the internal cavity of the container body. Containers have options for the design of the hull, options for filling with fire extinguishing agents and the execution of the mechanisms of formation of combustion and explosion. The essence of the invention disclose the following essential features.

Analogues of the methods for the container delivery of extinguishing agent from a remote distance to the fire, as well as the design of the barrel-type installations for the delivery of containers and the design of containers for delivering extinguishing agents to a remote distance, are not known to the applicant. The conducted literature and patent studies did not confirm the presence of existing analogues in domestic and world practice. It is known that to extinguish a fire at a remote distance from the fire, a method of delivering a jet of water under pressure using hand and gun shafts, as well as foam generators, are used. There is a wide variety of hand barrels that firefighters use when approaching a fire and suppressing it. Manual trunks include, for example, trunks: PC-50, PC-70, Fig. 1.20, p. 52 [1], RSKP-50 barrel, hand-held pistol-type barrel, RSP, Fig. 1.21, p. 52 [1] and others . Fire monitors, in which water or foam solutions are used as extinguishing agent under pressure, are designed to produce more powerful water or foam jets, and to deliver extinguishing agent from a remote distance to the fire. The fire monitors include: portable barrel PLS-20P, fig. 1.22, p. 54 [1], stationary fire monitor combined barrel PLS-60KS, fig. 5.6, p. 356, stationary barrel СПЛК-20С, fig. 5,7 [1], the gun mount LS-1, Fig. 36, p. 172 [2] and others. The gun mounts are more often used as water jet installations. Mobile fire monitors are usually installed on fire engines or fire trucks. The disadvantages of these types of stem devices include: low application efficiency due to significant scattering and evaporation of liquid jets, low efficiency; lack of universality in the application of various types of extinguishing agents, only one type of extinguishing agent is used - either water or foam solutions; low suppression power of the fire source per one barrel; increased danger of working with trunks in the fire zone. These shortcomings do not allow the effective use of fire monitors, not to mention hand guns to suppress primarily complex and large types of fires. As an analogue of the proposed fire extinguishing installation for container delivery in part of the fire extinguishing device, a stem type fire extinguishing installation is proposed, RF patent No. 2179048 [3]. The barrel type fire extinguishing installation according to patent No. 2179048 is made telescopic, has a fire extinguishing device with the ability to rotate and extend the barrel in space at various distances with the distance from the fire. But this installation according to the technical solution of patent No. 2179048 does not have the possibility of container delivery of fire extinguishing substances.

Signs of the proposed technical solutions that coincide with the prior art technical solutions and analogues are: the barrel type fire extinguishing installation includes a fire extinguishing device with the ability to rotate the barrel in a vertical and horizontal plane; the fire extinguishing device is placed on a rack and platform, has a barrel for supplying a fire extinguishing agent, electric drives for turning the barrel in space.

The objective of the invention is the creation of means and automatic fire extinguishing systems of high efficiency for use in the conditions of occurrence, localization and elimination of various types of fires due to the container delivery of fire extinguishing substances using barrel type fire extinguishing installations.

The technical result of the invention. For the first time in world practice, the container delivery of extinguishing agents from a remote distance to the fire using a barrel-type fire extinguishing system has been proposed. Containers can be filled with various types of fire extinguishing agents, covering various areas of practical application of the container delivery method and barrel type fire extinguishing installations. The proposed method of container delivery does not apply to cartridge-projectile methods of firing or delivery with powder charges or other charges.

In the proposed technical solutions, the driving force of the containers inside the barrel of the fire extinguishing installation is the vortex flow of gas or liquid under pressure. The containers inside the barrel rotate and move one after the other in a continuous flow in a floating state with a speed of regulation of the vortex flow. The proposed method is a combined system for supplying extinguishing agents in containers and a working medium of a vortex gas or liquid flow with adjustable pressure up to high pressure. Gaseous or liquid extinguishing agents together with extinguishing agents packed in containers can also be supplied as a working medium — a gas or liquid of a vortex stream. Using stem-type fire extinguishing installations and turbines for the formation of moving vortex flows integrated in them, as well as regulation of the vortex flow pressure, delivery of containers with extinguishing agents is possible both at a great distance from the fire source and with a minimum approach to the fire source. This method has high efficiency, versatility of application and high performance delivery of containers in a continuous stream to the fire, the ability to cover various sizes, including vast, volumes and areas of fire zones. In addition, fire extinguishing installations, while maintaining manual control, have control options: automatic self-guidance, remote control. The barrel is rotated at various angles in the vertical plane and the fire extinguishing device is rotated up to 180 ° in the horizontal plane.

Essential features. When the above technical result is achieved in the proposed method and its variants, the extinguishing agent is pre-packaged in containers and used as a means of delivering the extinguishing agent to the fire using a barrel type fire extinguishing installation. A container is pushed through the store by the pusher into the chamber cavity of the chambering device, the container is centered by the orientators, pushed by the pusher into the turbine vortex flow pipe, the container is cut off by the rebound restrictors, and the vortex gas or liquid flows through the channel system. The containers are rotated and moved in the inner cavity of the barrel in a vortex flow in a floating state, acting on the rear end part of the container (rear wall) to form an annular gap filled with a vortex flow under pressure between the outer surface of the container and the inner surface of the barrel. To carry out the method for the container delivery of extinguishing agent, the essential signs of the effects of the vortex flow impact on the containers were determined: the impact of the vortex flow in an open turbine directly in the inner cavity of the vortex flow tube, the impact of the vortex flow in a closed turbine directly in the inner cavity of the barrel inlet. To implement the method of container delivery of a fire extinguishing agent, designs of a barrel-type fire extinguishing installation and containers for delivering a fire extinguishing substance with options are proposed. In the fire extinguishing installation, the fire extinguishing device has a receiver rotating on a rack with an electric drive, in which a barrel with containers is fixed in the inner cavity of the barrel. The receiver and the barrel on the supply side of the containers are connected to a turbine for rotating and moving containers inside the barrel by means of a rotating vortex flow of gas or liquid. On the turbine casing, on the opposite side with respect to the barrel with the receiver, a device is installed for sending the container to the central zone of the turbine. A store-drive with containers is fixed on the body of the sending device. The internal cavity of the barrel, the central zone of the turbine and the internal cavity of the blowing device are aligned and make up a single internal cavity of the fire extinguishing device. In the central zone of the turbine casing there is a vortex flow tube in the form of a cylindrical container placement section. The pipe is connected to the vortex flow channel system. From the side of the connection of the turbine with the receiver, the inner cavity of the vortex flow pipe is smoothly interfaced with the inner cavity of the inlet of the barrel. The swirl flow pipe is made in two versions. An open type vortex flow pipe is made with a smooth change in the diameter of the cross-sectional profile of the internal cavity. The channel system is interfaced with the internal cavity of the vortex flow pipe and is brought directly to the central zone of the turbine casing. The closed vortex tube is made with a constant diameter of the cross-sectional profile of the internal cavity. The internal cavity of the vortex flow pipe is isolated in the turbine housing from the channel system. The system of channels of the turbine is brought out to the end of the turbine body directly to the inlet of the barrel and smoothly interfaced with the internal cavity of the inlet of the barrel. On the connection side of the turbine with the sending device, a group of orientators and limiters of the container rebound in the vortex flow pipe are located axisymmetrically in the turbine housing. The container is centered by the orientators in front of the vortex flow pipe. The container alignment orientators are located symmetrically relative to the axis of the vortex flow pipe. Each orientator is made in the form of a two-shouldered lever on the axis of rotation. One shoulder is adjacent along the line of touch in the initial position to the front cone of the container. In the working, pressed position, the shoulder of the orientator lever is adjacent to the outer cylindrical surface of the container. The second shoulder of the two-arm lever is connected to the tension spring. In the proposed technical solution, the limiters of the container rebound are made together with the orientators on the continuation of the two shoulders lever in the form of an inclined protrusion. The protrusions of the bounce limiters are located axisymmetrically from the back of the container located in the vortex flow pipe. On the outside of the turbine housing, a device for supplying and distributing gas or liquid under pressure is installed. The supply and distribution device is connected to nozzles on the turbine housing and is connected to a system of channels for the formation of a vortex flow. The channel system has options. The channel system in the turbine housing according to the first embodiment is made with a centralized supply of gas or liquid through a common nozzle on the turbine housing. The nozzle is connected to all channels. According to the second embodiment, the channel system is made in the turbine housing with channels of the distributed supply of gas or liquid through a group of nozzles on the turbine housing. Each nozzle is individually connected to a separate channel. The device for supplying and distributing gas or liquid on the turbine housing contains a distribution manifold, flow and pressure regulators of the supplied gas or liquid under pressure, a distribution box (distribution of gas or liquid flows), nozzles connected to inlet nozzles. In relation to the turbine, there is a pressure chamber in the body of the sending device. Coaxially with the sending cavity, a push rod (feeder) with an electric drive of axial movement of the container is installed in the housing of the sending device. The cavity cavity is located between the pusher and the orientators of the turbine. Sensors for monitoring the axial position of the container are located on the lower side of the body of the sending device. The sensitive elements of the sensors are communicated with the cavity cavity. A store-drive for the single-unit dispensing of containers into the delivery chamber is located and fixed on the housing of the delivery chamber. Containers for implementing the method of containerized delivery of extinguishing agent have design options. The container body is made in the form of a detachable or one-piece capsule of a box-shaped cylindrical shape, filled with a homogeneous or inhomogeneous extinguishing agent and, if necessary, combustion and explosive formation mechanisms. A prefabricated detachable container has at least one connector: longitudinal or transverse, from the front, rear side of the case. By filling the container has options. According to option 1, the container is made of plastic material, contains a counterweight in the head part with a shock mechanism for the formation of a chemical reaction. The impact mechanism has a push button on the counterweight outside the head. Inside the container body is filled with the alkaline part of the extinguishing agent, has a sealed flask with the acid part of the extinguishing agent. The flask contains a membrane that isolates the acidic part of the extinguishing agent in it from the alkaline part inside the container body. The flask is placed in the alkaline part. When the flask membrane is destroyed by the shock mechanism inside the container from the action of the button, the acid and alkaline parts are combined with the formation of foam and destruction of the container during the chemical reaction. In option 2, a set of special fire grenades is placed in a container of plastic material. Grenades are packed in a sealed shell with leads from them fire-resistant cords. Grenades are made spherical or cylindrical in shape. A fire extinguisher, an explosive charge, a fuse are placed inside the grenade body. Fire-resistant cords are displayed in the form of an ignition unit outside the container body. The ignition unit outside and the fire cords inside the container body are connected with fuses and explosive charges of grenades. According to option 3, the container body is made of durable material. Inside the case is covered with a protective heat-resistant shell. In the housing there are through holes distributed on the cylindrical part, communicating the internal cavity of the container with the external environment. The holes are made with nozzles flowing through them from the inner cavity of the container body of the chemical reaction and combustion products. Inside the container body is filled with an aerosol forming composition. In the head of the container there is a combustion and explosion mechanism. It consists of a powder charge and a fire-conducting cord, which is in communication with the charge and removed from the internal cavity of the housing to the outer side of the head. According to option 4, the container of plastic material consists of detachable parts - the head and cylindrical. The cylindrical part is made with a thermally destructive body, filled with a fire extinguishing agent. The cylindrical part at the junction with the head part contains a sleeve with a through hole for filling the internal cavity with a fire extinguishing agent. The head part of the container contains a thermal explosion device, is connected to a cylindrical one and closes the through hole of the sleeve. In option 5, the container consists of a head and a cylindrical part. The cylindrical part is made with a heat-destroying case, filled with a partially reactive inhibitor under pressure and hermetically sealed with a screw plug. The head part is screwed onto the external thread of the plug and secured against the cylindrical part. The invention is characterized by all the features included in the claims.

Figure 1 shows the installation of fire extinguishing the barrel type, a General side view; figure 2 - fire extinguishing device fire extinguishing stem type, longitudinal section, side view; figure 3 - fire extinguishing device fire extinguishing stem type, top view; figure 4 is a section aa, figure 2; figure 5-8 shows the options for the turbine in cross section BB, figure 3; figure 9 is a device duplication along section bb, figure 2; figure 10 - orienting the centering of the container along the cross section GG, figure 2; 11-16 show options for containers in the form of a capsule box-shaped cylindrical; on Fig - a container with a shock mechanism; in Fig.18 - a container with fire grenades; Fig.19 is an aerosol type container; in Fig.20 - container thermal explosion action; on Fig - container with a chemically active inhibitor.

The barrel type fire extinguishing installation (Fig. 1) has a fire extinguishing device 1 with a barrel 2, a rack 3 with a rotation drive 4 relative to the horizontal axis, a turntable 5 with a rotation drive 6 relative to the vertical axis О _h -О _h . Fire extinguishing device 1 (figure 2, 3) contains the following main components and mechanisms. The barrel 2 is installed and fixed in the receiver 7. In the inner cavity of the barrel 2 are located the containers 8. During the movement, the containers 8. The containers 8 have a cylindrical part of the surface 9 and a tapered conical inlet part 10. The containers 8 are filled with a fire extinguishing agent. They also contain mechanisms of action on extinguishing agents, on the formation of combustion processes or on the production of an explosion. On the housing of the receiver 7 are installed on both sides of the axis 11, 12 of rotation, figure 3, in the form of shafts with bearing bearings 13, 14. The receiver with axles 11, 12, assembled in a node with a barrel 2 on bearing bearings 13, 14, placed on a two-post rack 3. On one side of the rack 3 there is a gearbox 15, for example a worm gear, an electric drive 4 for rotating the fire extinguishing device 1 as a whole relative to the horizontal axis O _v -O _v in a vertical plane. The worm gear 16 of the gearbox 15 is fixed on the axis 12 of the receiver 7. The manual rotation handle 17 is connected to the worm and the worm gear by a switching clutch (not shown) 16. The receiver 7 and the barrel 2 are connected to the turbine from the supply side to the barrel 2 of the container 8 18 rotation and movement of containers 8, for example using bolts 19, figure 2, 3. In the Central zone of the turbine housing 18 there is a swirl flow pipe of open type 20, figure 2, or closed type 21, figure 3. The pipe 20, 21 is made in the form of a cylindrical portion of the container 8 in the Central zone of the turbine housing 18. From the side of the connection of the turbine 18 with the receiver 7, the inner cavity of the pipe 20, 21 of the vortex flow smoothly mates with the inner cavity of the inlet part of the barrel 2. In the turbine housing 18 there is a system of channels 22 for the formation of a vortex flow, which is connected to the pipe 20, 21. On the outside of the turbine housing 18, a device 23 for supplying and distributing gas or liquid under pressure is installed, which is connected to the inlet nozzles E 24, 25 of the turbine housing 18, 5-8. The nozzles 24, 25 are in communication with the channel system 22 inside the turbine 18. The nozzles 24 are made with a distributed supply, FIGS. 5, 6, and the nozzle 25 with a centralized supply, FIGS. 7, 8 of gas or liquid into the channel system 22. The channel system 22 for distributed supply has several channels 22 ¹ , 22 ² , 22 ³ , 22 ^{4 for} supplying gas or liquid to the vortex flow pipe 20, 21.

On the opposite side of the turbine housing 18 with respect to the barrel 2, the turbine 18 is connected, for example, by bolts 26, to the dispensing device - a rammer 27 of the container 8 into the central zone of the turbine 18, Figs. 1, 2, 3, 9. There is a cavity inside the dispensing device 27 chamber 28, a pusher 29 with a spring 30 is installed. On the housing of the chamber 27, an electric actuator 31 for axial movement of the plunger 29 is placed. The electric actuator 31 is kinematically connected to the pusher 29 with a gear 33, for example pinion gear 29. The cavity 28 placed between the pusher 29 and the entrance to the Central zone of the turbine housing 18. On the lower side of the housing of the sending device 27 there are sensors 34 for monitoring the axial position of the container 8 in the space of the pressure chamber 28. Sensing elements 35 of the sensors 34 are passed through the holes in the pressure chamber 28. Above on the device body sent 27 store store 36 piece delivery and loading of containers 8 ¹ , 8 ² , ... 8 ⁿ , Fig.2.9. The case of the magazine 36 is placed above the chamber of the chamber 28, for example, by bolts 37. The internal cavity of the magazine 36 is in communication with the internal cavity of the chamber of the chamber 27 so that the container 8 ¹ from the number 8 ¹ , 8 ² , ... 8 ^{n is} placed in the chambering chamber 28 coaxially to the axis of the pusher 29. On the side of the chambering device 27 in the turbine housing 18 orientators 38 are provided for centering the container 8 in front of the vortex flow pipe 20, 21 with a bounce limiter of the container 8 in the vortex flow pipe 20, 21, FIG. 2, 3, 10. Orienters 38 centiri The bearings are arranged symmetrically with respect to the axis of the pipe 20, 21 in the pockets 39 in the turbine housing 18. The orientator 38 is made in the form of a two-shoulder lever 40, on the pivot axis 41. One shoulder 42, Fig. 2, of the lever 40 has its end part so that in the original adjacent to the position along the touch line to the front cone 10 of the container 8 before entering the container 8 and when the vortex stream of the turbine 18 enters the pipe 20, 21. The second shoulder 43 is connected to the lever return mechanism, for example, a tension spring 44 so that when the container 8 moves, the lever 40 in work polo rotation is turned and the shoulder 42 is adjacent to the surface of the cylindrical part 9 of the container 8. The rebound limiter is made together with the orientator 38 on the extension of the shoulder 42 of the two-arm lever 40 in the form of an inclined protrusion 45. The protrusions 45 of the rebound limiters on the orientators 38 are located axisymmetrically from the rear end of the container 8, located in the tube 20, 21 of the vortex flow in the turbine 18 with the possibility of touching the protrusions 45 of the rear end of the container 8 when the container bounces.

In the turbine 18, the vortex flow pipe 20, 21 and the system of channels 22 of the vortex flow formation have options. According to the first embodiment, the vortex flow tube 20, Figs. 2, 5, 7, 4, is made of an open type. The pipe 20 has a smooth change in the diameter of the cross-sectional profile of the inner cavity and is brought directly to the central zone of the turbine housing 18. The channel system 22 is coupled to the internal cavity of the pipe 20 so that the vortex flow on the container 8 is carried out in the central zone of the turbine housing 18. According to the second embodiment, the pipe 21, Figs. 3, 6, 8, are closed type, the inner cavity of the pipe 21 has a constant diameter of the cross-sectional profile and is isolated from the channel system 22 in the turbine housing 18. The channel system 22 is brought out to the end of the turbine housing 18 and directly into the input of the barrel 2 and smoothly interfaced with the internal cavity of the input of the barrel 2.

The channel system 22 has the following designs. The channel system 22 according to the first embodiment, Figs. 7, 8, in the turbine housing 18 is made with a centralized supply of gas or liquid under pressure into the vortex flow pipe 20, 21 through a common inlet nozzle 25 on the turbine housing 18. The nozzle 25 is connected to the channel system 22 According to the second variant, the system of channels 22, Figs. 5, 6, 4, is made in the housing 18 with channels 22 ¹ , 22 ² , 22 ³ , 22 ^{4 of a} distributed supply to the pipe 20, 21 of a vortex flow of gas or liquid under pressure through a group of inlets nozzles 24 on the turbine housing 18. Each nozzle 24 is individually connected to one of the channels 22 ¹ , 22 ² , 22 ³ , 22 ⁴ .

The device for supplying and distributing 23 gas or liquid under pressure, Figs. 2, 3, 4, is located outside the turbine housing 18 and is connected to the inlet nozzles 24 or 25. The device for supplying and distributing 23, Fig. 4, contains a distribution manifold 46, regulators 47 the flow and pressure of the supplied gas or liquid for each nozzle 24, distribution carrier block 48, nozzles 49. The internal holes of the nozzles 49 are associated with the inlet nozzles 24 in the turbine housing 18.

In the nodes of the fire extinguishing device 1, the inner cavity of the barrel 2 in the receiver 7, the vortex flow pipe 20, 21 in the central zone of the turbine housing 18, the pressure chamber 28 and the pusher 29 in the pressure chamber 27 are aligned and form a single cavity in which the containers 8 are placed with packed fire extinguishing substances, figure 2, 3. Containers 8 inside the fire extinguishing device 1 make up the total flow of containers 8 continuously moving with rotation in the barrel 2 one after another 8 with repeating cycles of the pusher 29.

The containers 8 for the delivery of extinguishing agents are made in the form of a capsule 8 ¹ ... 8 ⁶ , preferably a box-shaped cylindrical shape, 11-16. The container 8 has an outer cylindrical 9 and inlet conical 10 conical shape of the surface. The end rear surface of the container 8 has a large area with respect to the area of the end front surface. The internal cavity of the container is closed, the fire extinguishing substances 50 filling it and the mechanisms of excitation or the formation of a chemical reaction, combustion or explosion are placed in it. The container body 8 has options, 11-16. The container 8 is made with a prefabricated housing 8 ² , 8 ³ , 8 ⁴ , 8 ⁵ , 8 ⁶ and a fire extinguisher 50 sealed inside the housing, FIGS. 12-16. The container 8 is made with an integral housing 8 ¹ , with a fire extinguishing agent 50 hermetically sealed in it, Fig. 11. The container 8 with the prefabricated housing 8 ³ , 8 ⁴ contains a removable head part 51, Fig.13, 14, and has a connector on the front side of the container 8 ³ , 8 ⁴ . The container 8 with the prefabricated housing 8 ⁶ , Fig.16, has a connector parts of the capsule longitudinal. The container 8 with the prefabricated housing 8 ⁵ , Fig.15, has a transverse connector parts. The container 8 with the prefabricated housing 8 ² , 8 ⁴ , FIG. 12, 14 contains a removable end part or a rear plug 52 and has a connector on the rear side of the container 8 on the end part.

The design of the container 8 for filling the housing with the mechanisms of formation of combustion or explosion along with fire extinguishing compositions and substances has options, Fig.17-21.

A variant of the container 8 with a shock mechanism, Fig.17. The container 8, the casing of which is made of plastic material, contains a removable head part - a counterweight 53, an impact mechanism 54 of the pressure action for the formation of a chemical reaction between the acid 55 and the alkaline part 56 of the fire extinguishing composition in the casing. Counterweight 53 is screwed onto the container body. The acidic part 55 is enclosed in an airtight flask 57 with a protective membrane 58, and the alkaline 56 in the cylindrical part inside the housing so that the flask 57 is immersed in the alkaline part 56. The shock mechanism 54 has a button 59 on top of the counterweight 53 with a spring 60. The shock mechanism 54 to the beginning of action inside the case is squeezed and located above the membrane 58 of the flask 57. The container body 8 is made with grooves 61, leading to destruction and rupture of the body when punched by the shock mechanism 54 of the membrane 58 and the combination of the acid and alkaline parts, accompanied by a chemical reaction tsiey.

Option container 8 with fire grenades, Fig. 18. In the container 8, the case of which is made of plastic material, a set of 62 of several fire grenades is placed 62 ¹ , 62 ² , 62 ³ ... 62 ⁿ . Grenades 62 are laid inside the cylindrical part of the body. Between the grenades 62, tool holders 63 were laid. The entire set of 62 grenades was packed in an airtight shell, not shown in the figure. Each grenade has a spherical or cylindrical shape and consists of a casing 64, inside which a fire extinguishing agent, for example powder 65, is placed. An explosive charge 66 of an explosive is placed inside the casing 64 with a fire extinguisher 65. After charge housing 64 held fuse 67 66. 67 grenade fuses 62 ^1, 62 ^2, 62 ³ ... 62 ^minutes summed fuse 68 with its pin in the head portion 69 of the container 8. The fuse 68 through the head portion 69 removed and stacked to the ignition unit 70 outside the head part 69 of the container 8. When a fire-conducting cord 68 is ignited from the assembly 70 outside the container 8, fuses 67 and explosive charges 66 are communicated and connected to the fire-conducting cords 68 inside the container 8 with the explosion, rupture of the container body 8 and the exploded grenades 62 with extinguishing agent tion.

A variant of the container 8 aerosol type, Fig.19. The container 8, the casing of which is made of durable material, is coated inside with a heat-insulating and protective shell 71. The cylindrical part of the casing of the container 8 has through holes 72 that are distributed over the surface of the casing and communicated with the internal cavity of the casing. The holes 72 are made in the form of nozzles 73 for the discharge of combustion products from the inner cavity of the container 8. The inner cavity of the container 8 is filled with an aerosol forming composition 74. In the head part 75 of the container 8 there is a protruding fire-resistant cord 76. Through the head part of the fire-conducting cord 76 is connected to the ignition charge 77, for example, powder.

Option container 8 thermal explosion action, Fig.20. The container 8, the housing of which is made of plastic material, consists of detachable parts — the head part 78 and the cylindrical 79. The cylindrical part 79 at the junction with the head 78 has a sleeve or sleeve 80 with a through hole 81 secured by a nut 82. The internal cavity of the cylindrical part 79 filled with liquid or powder extinguishing agent 83. The head part 78 is connected to the cylindrical 79 with sealing and overlapping the through hole 81 in the sleeve 80. The cylindrical part 79 is thermally decomposable with the possibility of expansion extinguishing agent, and the head portion 78 further comprises a device 84 termovzryvnoe.

A variant of the container 8 with a reactive inhibitor, Fig.21. The container 8, the casing of which is made of plastic material, consists of detachable parts - the head 85 and the cylindrical 86. The cylindrical part 86 at the junction with the head 85 has a fixed threaded sleeve 87 with a through hole 88. Through the hole 88, the inner cavity of the cylindrical part 86 is chemically filled active inhibitor 89 under pressure and hermetically sealed: threaded plug 90 is screwed onto threaded sleeve 87 and fixed, blocking bore 88. Head part 85, in turn, is screwed onto threaded outer h part of the plug 90 and is pressed against the end of the cylindrical part 86. The cylindrical part 86 of the container 8 is thermally destructive with a spray of a reactive inhibitor upon heating and destruction of the container 8.

The design of the fire extinguishing installation and containers 8 provide an implementation of the method of container delivery of fire extinguishing substances to the fire. Initially, the container bodies 8 are filled with a fire extinguishing agent, packaged, and filled with combustion and explosion mechanisms. Containers 8 are loaded into the store 36 on the body of the dispensing device - rammer 27, Figs. 2, 3, 9. The container 8 is fed with the pusher 29 into the dispensing cavity 28 of the dispensing device 27 from the magazine 36 in the direction of the turbine 18. The container 8 moved by the pusher 29 is centered by axisymmetric orientators 38 in front of the vortex flow pipe 20, 21 in the turbine housing 18, push it with a pusher 29 through the orientators 38 into the pipe 20, 21 and cut off the return stroke towards the air chamber 28 of the container 8 located in the pipe 20, 21 with the protrusions 45 of the rebound stoppers. In the pipe 20, 21 they act on the concentrated container 8 by a vortex flow of gas or liquid under pressure through a system of channels 22, rotate and move the container 8, directing it into the internal cavity of the barrel 2. For an open type turbine 18, they act by the vortex on the container 8 in the internal open cavity pipes 20, FIGS. 2, 5, 7, 4. The impact zone is located directly in the turbine housing 18. For a closed type turbine 18, they act on the container 8 in a vortex flow outside the turbine housing 18 directly in the inlet cavity th part of the barrel 2, Fig.3. The impact zone is moved outside the turbine housing 18 to the inlet of the barrel 2. The vortex flow, which is distributed inside the barrel 2, acts on the rear end part and on the outer cylindrical surfaces 9, 10 of the container 8 with the formation of an annular gap 91, filled under high pressure by a vortex flow between the outer cylindrical surface 9 of the container 8 and the inner surface of the barrel 2, Fig.2, 3.

Installation fire extinguishing figure 1, 2, 3, which implements the method of container delivery of fire extinguishing substances, works as follows. To orient the barrel 2 in space, the rack 3, mounted on the platform 5, together with the fire extinguishing device 1 and the barrel 2, is rotated in a horizontal plane relative to the vertical axis О _h -О _h using electric drive 6 in the direction of the fire source. Next, the fire extinguishing device 1 of the installation is rotated on the rack 3 using an electric drive 4, rotate the barrel 2 relative to the horizontal axis O _v -O _v . When the fire extinguishing device 1 is rotated, the electric drive 4 through the reducer 15 with the worm and the worm wheel 16 on the axis 12 rotates the receiver 7 on the axes 11, 12 with the barrel 2 in a vertical plane. The control of rotation and rotation of the fire extinguishing device 1 with the barrel 2 on the rack 3 in both vertical and horizontal planes is possible in various modes. The inclusion of electric drives 4 and 6 provides the rotation of the fire extinguishing device 1 in control modes: automatic, remote, commissioning. In the commissioning or manual control mode, the handles 17 of the traditional design are rotated. Containers 8 are filled with extinguishing agents with uniform or heterogeneous properties. A group of containers 8 are loaded one after the other into the magazine store 36 above the cavity of the rammer 28 and the containers 8 are placed in the inner cavity of the housing of the dispenser 27, vertically arranged 8 ¹ , 8 ² , ... 8 ⁿ . The first of the group, the container 8 ¹ enters the pressure chamber 28. In this case, two sensors 34 use the sensing elements 35 to monitor the axial position of the container 8 ¹ in the pressure chamber 28. If the container 8 ^{1 is} horizontally aligned with the axis of the fire chamber 28, aligned with the axis of the fire extinguishing device 1 and barrel 2, then the signals from two sensors simultaneously in the control system give the command to turn on the electric drive 31 with the gearbox 32. The pusher 29, pressed by the spring 30, receives axial movement through the rack and pinion gear 33 from drive 31 and move the container 8 ¹ from the store 36, into the delivery chamber 28 towards the central zone of the turbine 18. The container 8 ¹ pushed by the pusher 29 into the rear end face is passed through the orientators 38. The orientators 38 are located axisymmetrically on the turbine housing 18 from the mounting side turbines 18 with the body of the sending device 27 and center the container 8 ¹ , orienting it strictly coaxially to the vortex flow tube 20, 21 in front of the central zone of the turbine body 18. At the same time, in the initial position, the arms 42 of the levers 40 ntators 38 embrace and fit along the line of contact to the front conical part 10, previously orienting the container 8 ¹ , and then, as the container 8 ¹ moves in contact with mechanical action, turns the levers 40 to the working position relative to the axes 41 and the shoulders 42 cover the container 8 ¹ adjacent to the outer surface of the cylindrical part 9 of the container 8 ¹ . The container 8 ¹ , pushed by the pusher 29, in a concentrated position enters the pipe 20, 21, in the central zone of the turbine body 18. The levers 40 of the orientators 38 are returned by tension springs 44 to their original position as soon as the cylindrical part 9 of the container 8 ¹ from the rear the end comes out of contact with the shoulders 42 of the lever 40. In this case, the rebound stoppers made in conjunction with the levers 40 of the orientators 38 are in the form of inclined projections 45 set axially symmetrically from the rear end part of the container 8 ¹ and prevent the possibility of Bounce or reverse the container 8 ¹ . The pusher 29 is withdrawn from the chamber cavity 28 and returned to the initial, initial position by the electric drive 31. The following, another container 8 ² with the possibility of its subsequent pushing behind the container 8 ^{1 with the} pusher 29 is placed to the vacated place from the departed container 8 ¹ in the delivery chamber 28 from the store 36. With the continuation of the movement of the container 8 ¹ in the central zone, in the pipe 20, 21 of the case turbine 18 in the direction of the barrel 2, the container 8 ¹ , like any subsequent container 8, is carried away by the vortex flow, maintains centering, receives rotation and translational movement. The vortex flow is created by the pipe 20, 21, the system of channels 22 and the supplied gas or liquid under pressure through the supply and distribution device 23 connected to the system of channels 22 on the turbine casing 18. The vortex flow pipe 20, 21 is located in the central zone of the turbine casing 18. The pipe vortex flow is used in two versions and the principle of operation in the turbine 18. The pipe 20, Fig.2, 5, 7, is made of an open type. The channel system 22 is coupled to the internal smoothly varying cavity of the pipe 20 and is discharged into the central zone of the turbine casing 18. The vortex flow on the container 8 is carried out in the pipe 20 directly in the turbine casing 18. For the second embodiment, the vortex flow pipe 21 is closed, Fig. 3 , 6, 8. The inner cylindrical cavity of the pipe 21 is closed from communication with the channel system 22 in the turbine housing 18. And the channel system 22 has no exit to the central zone and is not directly connected with the pipe 21 in the turbine housing 18. The channel system 22 is closed of the type of pipe 21 is brought out to the end of the turbine housing 18, mated to the internal cavity of the inlet part of the barrel 2 and directs the vortex flow directly to the inlet part of the barrel 2. The channel system 22, in turn, has options and generates a vortex flow in various modes: centralized and distributed vortex flow formation. In a centralized embodiment, gas or liquid is supplied into a single channel system 22 or a common channel through a common inlet nozzle 25 on the turbine housing 18, Figs. 7, 8. According to a distributed version of the channel system 22, gas or liquid from the supply and distribution device 23 is supplied through a group of input nozzles 24, each connected to a separate channel of the channel system 22 ¹ , 22 ² , 22 ³ , 22 ⁴ , FIGS. 5, 6. In each of the channels 22 ¹ , 22 ² , 22 ³ , 22 ⁴ , an individual mode of formation of jets and combining them to form a vortex flow .

In the turbine 18, gas, for example air, or liquid, for example water, is supplied from the compressor under pressure to the manifold 46 of the supply and distribution device 23, FIG. 4. Then the gas or liquid is divided into the number of independent flows equal to the number of channels 22 ¹ , 22 ² , 22 ³ , 22 ⁴ in the channel system 22, or sent to a single stream for centralized supply. The flow rate and pressure of the gas or liquid is controlled using regulators 47. Then, through the inlet nozzles 24 or 25, they are directed into the channels of the channel system 22 with the subsequent formation of a vortex flow according to the embodiment of the pipe 20, 21. The vortex flow formed in the turbine 18 is distributed in the barrel 2, acts on the rear end part and the outer cylindrical surface of the containers 8, fills under high pressure the annular gap 91 between the outer surface of the container 8 and the inner surface of the barrel 2, figure 2, 3. The vortex flow rotates and moves containers 8 inside the barrel 2 in a floating state in a continuously moving stream.

Containers 8 using a fire extinguishing installation implement the method of container delivery of fire extinguishing substances and work as follows. When the container 8 passes inside the barrel 2, the vortex flow affects the outer surfaces of the container 8. The design of the container 8 is such that the greatest force of the vortex flow is directed to the rear end of the container body, while the vortex flow moves the container 8 in the axial direction and rotates the container 8 uniformly acting along the perimeter on a cylindrical 9 and conical 10 surface with a distribution of forces along the tangent (rotation of the container) and along the normal (floating of the container inside the barrel without tang Nia). The area of the rear end surface is of greater importance with respect to the area of the front end surface, and the conical surface 10 has a constant or variable cone angle and a shorter length with respect to the length of the cylindrical surface 9.

Containers 8 in the form of a capsule are pre-filled with extinguishing agents, combustion mechanisms, chemical reactions, or explosions. Containers 8, delivered by a fire extinguishing installation to a fire at a distance, are exposed to heat and shock. When exposed to temperature and / or shock, the container body is destroyed, suppressed and eliminated the fire. The container body 8 is preferably used in a cylindrical shape having a conical surface 10 and a cylindrical surface 9. The internal cavity of the containers 8 is sealed. In this case, the containers 8 are used with one-piece or detachable housing, 11-16. Detachable cases have removable head or rear end parts, Fig.12, 13, 14. Each of them is used to provide technical and operational characteristics, solving design and technological problems. The most simple to assemble are the case with a longitudinal and transverse connector, Fig.15, 16. But they have less accuracy and manufacturing quality of the cylindrical part of the container compared to detachable and one-piece cases, Fig.11, 12, 13, 14.

Both for the filling of the internal part, and for its intended purpose, there are options for the design and purpose of containers with detachable and integral bodies. The container 8 (Fig.17) is made of shock. In the process of hitting the button 59 as opposed to 53 about a solid object in the fire, the shock mechanism 54 breaks the membrane 58, the acid part 55 in the flask 57, emerging, mixes with the alkaline part 56. As a result of the chemical reaction of the acid 55 and alkaline 56 parts, the pressure inside the case increases container. Under the influence of internal pressure, chemical reaction, external temperature exposure, the body with grooves 61 is destroyed with the formation and spraying of chemical foam. The maximum extinguishing area per container (Fig. 17) is 3-5 m ² with a diameter of the cylindrical part of the container 8 cm. Container 8 (Fig. 18) is made with fire grenades and is triggered by the action of a flame. In the container body 8, made of plastic material, a set of grenades 62 is packaged in an airtight shell. The grenades 62 are spherical or cylindrical in shape and stacked along the container body 8. When ignited from the outside of the head part 69 of the ignition unit 70 of the fire-resistant cord, through fire-resistant cords 68 from the ignition unit 70 inside the container 8 with the help of a fuse 67 explosive charges 66 are triggered and all grenades 62 explode. The case is made of plastic material of the container. Grenades 62, exploding, fly apart, scattering the extinguishing agent 65. It is preferable to use containers (Fig. 18) for enclosed spaces with a maximum extinguishing area of one container up to 10-15 m ² . The container 8 (Fig.19) aerosol type. A fire extinguishing agent is an aerosol forming composition. During combustion, gases are formed - aerosol. It is preferable to use containers to extinguish fires in enclosed spaces. When the container enters the fire, the fire-resistant cord 76 lights up outside the head part 75, which ignites the powder charge 77. In the process of burning the aerosol-forming composition 74 through the holes 72 with nozzles 73 in the container body, the aerosol sharply releases and expires. When the container is triggered during the fire extinguishing, the aerosol covers an area of up to 15-20 m ² for one container with a case diameter of 8 cm. Container 8 (Fig. 20) has a thermal explosion effect. Extinguishing agent 83 - powder used in fire extinguishers. The case of the cylindrical part 79 of the container is made of plastic material, and the head part 78 includes a thermo-explosive device 84. A fire extinguisher 83 is introduced into the inner cavity of the cylindrical part 79 through an opening 81 in the threaded sleeve 80. The sleeve 80 is fixed by a nut 82. The hole 81 in the head part 78 is closed thermal explosive device 84. With thermal exposure in the fire, the pressure inside the cylindrical part 79 increases several times. In addition, a thermal explosion device accelerates the heating of the container and the rupture of its plastic casing. Fire extinguishing agent 83 - the powder scatters, covering the fire source up to 6-8 m ² for one container with a diameter of 8 cm. It is advisable to use containers 8 (Fig. 20) for both surface and volume extinguishing methods, both in open areas and in in enclosed spaces. Container 8 (Fig.21) with a chemically active inhibitor. Fire extinguishing agent 89 - a chemically active inhibitor is injected under pressure in portions through the hole 88 in the threaded sleeve 87 of the cylindrical part 86 of the container. The cylindrical part 86 with the inhibitor is hermetically sealed with the plug 90, screwing it onto the nut 87 and blocking the hole 88. The head part 85 is fixed, screwed onto the external thread of the plug 90 and pressed against the front end of the cylindrical part 86. During thermal exposure in the focal zone of the cylindrical part 86 of the container from a plastic material, the pressure rises and the body collapses with a spray of a chemically active inhibitor with a maximum coverage of the fire site with an area of up to 5-6 m ² for one container.

Literary and patent sources

1. Fire fighting equipment. 1. Fire-technical equipment / ed. A.F. Ivanova. - M .: Stroyizdat, 1988.

2. Shuvalov N.G. Firefighting Basics. - M .: Stroyizdat, 1983

3. RF patent No. 2179048. Barrel type fire extinguishing installation / А.М. Tsarev, N.G. Kolpin // Bulletin of inventions. - 2002. - No. 4.

Claims (25)

1. A method for the container delivery of extinguishing agent, characterized in that the extinguishing agent is pre-packaged in containers, a container is pushed through the store by the pusher from the chamber cavity of the chamber of the chambering device in the direction of the turbine, the container is centered by the orienters in front of the turbine swirl flow pipe, pushed into the pipe by the pusher swirl flow in a concentrated position and act by swirl flow of gas or liquid through a system of channels, rotate and move the containers to the inside the cavity of the barrel in a gas or liquid medium so that the vortex flow distributed inside the barrel acts on the rear end of the container and regulates its speed with the formation of an annular gap filled with a vortex flow under pressure between the cylindrical surface of the container and the inner surface of the barrel, cut off the return stroke of the container in the pipe by the limiters of the rebound. 2. The method of container delivery of extinguishing agent according to claim 1, characterized in that they act by vortex flow on the container in an open type turbine directly in the inner cavity of the vortex flow pipe inside the turbine casing. 3. The method of container delivery of extinguishing agent according to claim 1, characterized in that they act by vortex flow on the container in a closed-type turbine directly in the internal cavity of the barrel inlet outside the turbine casing. 4. A barrel type fire extinguishing installation for implementing a method with a stand-on fire extinguishing device, comprising a fire extinguishing agent supply barrel and a rotatable platform, characterized in that the fire extinguishing device has a receiver that rotates on a stand with a drive, in which a barrel with containers is fixed in the inner cavity of the barrel, the containers are filled with a fire extinguishing agent, and the receiver and the barrel on the supply side of the containers are connected to a turbine for rotating and moving containers inside the barrel By means of a rotating vortex flow of gas or liquid, from the opposite side of the turbine it is connected to the device for sending the container to the central zone of the turbine and the store-drive for piece delivery of containers so that the internal cavity of the barrel, the central zone of the turbine and the sending device are aligned. 5. The fire extinguishing installation according to claim 4, characterized in that the turbine has a vortex flow pipe in the form of a cylindrical container placement portion in the central zone of the turbine housing, the pipe being connected to the vortex flow channeling system, there is an internal cavity on the side of the turbine and receiver connection the vortex flow tubes smoothly interfaced with the internal cavity of the inlet part of the barrel, and from the side of the turbine connection with the body of the sending device, the container alignment orientators are placed in the turbine body and in front of the vortex flow pipe and container bounce limiters in the vortex flow pipe, while a device for supplying and distributing gas or liquid under pressure is installed on the outside of the turbine casing, which has connections with nozzles on the turbine casing connected to the system of vortex formation channels flow in the turbine housing. 6. The fire extinguishing installation according to claim 5, characterized in that the turbine vortex flow pipe is made of an open type with a smooth change in the diameter of the cross-sectional profile of the internal cavity, while the channel system is interfaced with the internal cavity of the vortex flow pipe and brought directly to the central zone of the turbine casing. 7. The fire extinguishing installation according to claim 5, characterized in that the turbine vortex flow pipe is closed-type with a constant diameter profile of the internal cavity section, while the internal vortex flow pipe cavity is isolated in the turbine body from the channel system, and the turbine channel system is led to the end the turbine housing and directly into the inlet of the barrel and smoothly interfaced with the internal cavity of the inlet of the barrel. 8. Fire extinguishing installation according to any one of paragraphs.5-7, characterized in that the channel system in the turbine housing is made with a centralized supply of gas or liquid through a common inlet nozzle on the turbine housing, and the nozzle is connected to all channels. 9. Fire extinguishing installation according to any one of claims 5 to 7, characterized in that the channel system in the turbine housing is made with channels of distributed gas or liquid supply through a group of inlet nozzles on the turbine housing, each nozzle being individually connected to a separate channel. 10. The fire extinguishing installation according to claim 5, characterized in that the device for supplying and distributing gas or liquid on the turbine housing contains a distribution manifold for supplying gas or liquid to the channel system, flow and pressure regulators of each channel, a junction box and nozzles connected to inlet nozzles . 11. Fire extinguishing installation according to claim 5, characterized in that the container centering orientators are located symmetrically relative to the axis of the vortex flow pipe, each of which is made in the form of a two-shouldered lever on the rotation axis, while one shoulder rests along the contact line in the initial position to the front conical parts of the container, and in the working, pressed position, to the outer cylindrical surface of the container, while the second shoulder is connected to the spring return the lever to its original position. 12. The fire extinguishing installation according to claim 5, characterized in that the container rebound limiters are made together with the orientators on the continuation of the two shoulders lever in the form of an inclined protrusion so that the protrusions are located axisymmetrically from the back of the container located in the vortex flow pipe. 13. The fire extinguishing installation according to claim 4, characterized in that the dispensing device has a housing with a dispensing cavity, in which a container pusher with an axial displacement drive is installed, wherein the dispensing cavity is located between the pusher and the container orientators in the turbine, from the bottom side of the dispensing device the axial position sensors of the container are located and connected to the delivery chamber in the delivery cavity, while the store-store of piece delivery of containers is placed on the housing of the delivery device above the strips Strongly chambering. 14. A fire extinguisher delivery container for implementing a container delivery method, characterized in that the container is in the form of a box-shaped capsule, has an outer cylindrical, inlet conical, end rear and front surfaces, in the inner closed cavity of the body of which fire extinguishing substances and combustion mechanisms are placed of these substances, chemical reactions and explosions, while the container body has an area of the rear end surface with a large value in relation to the front the front, conical surface with a constant or variable cone angle of a shorter length with respect to the cylindrical surface. 15. The fire extinguisher delivery container according to claim 14, characterized in that the container is made with a prefabricated detachable body with a fire extinguisher sealed therein. 16. The fire extinguisher delivery container according to claim 14, characterized in that the container is made with an integral body with a fire extinguisher sealed therein. 17. The container for the delivery of extinguishing agent according to 14 or 15, characterized in that the container contains a removable head and the prefabricated container body has a connector on the front side of the body. 18. The container for the delivery of extinguishing agent according to 14 or 15, characterized in that the container assembly has a longitudinal part connector. 19. The container for the delivery of the extinguishing agent according to 14 or 15, characterized in that the prefabricated container body has a transverse connector. 20. The container for the delivery of extinguishing agent according to claim 14 or 15, characterized in that the container contains a removable end part and the prefabricated container body has a connector on the rear side of the body. 21. The container for the delivery of a fire extinguishing agent according to any one of claims 14 to 20, characterized in that the container of plastic material contains a counterweight in the head part, a percussion mechanism for the formation of a chemical reaction, a sealed flask with the acid part of the extinguishing agent, an alkaline part of the extinguishing agent, the percussion mechanism has a push button on the counterweight outside the head part, which is connected inside the container to the impact device on the flask, and the flask is placed in the alkaline part of the extinguishing agent so that when the flask is destroyed by the impact mechanism, the acid part and the alkaline part of the extinguishing agent are combined with the formation of foam and the destruction of the container during the chemical reaction. 22. A fire extinguisher delivery container according to any one of claims 14 to 20, characterized in that a set of special fire grenades packed in a sealed enclosure is placed in a container of plastic material, fire-conducting cords are brought to the grenades with their leads outside to the ignition unit in the head part a fire extinguisher, such as a powder, explosive charge and fuse, so that the fire-resistant cords on the outside of the container and inside the container communicate with fuses and explosive charges poisons with explosive formation, destruction of the container body and scattering of grenades, fire extinguishing agent during the ignition of fire-resistant cords from the ignition unit. 23. The fire extinguisher delivery container according to any one of claims 14 to 20, characterized in that the container body is made of durable material, inside is covered with a protective heat-resistant shell, has through holes distributed on the cylindrical part and is filled with an aerosol-forming composition, a protruding head is placed in the head outside, a fire-retardant cord that is connected to a fire charge, such as a powder charge, inside the container, while the holes in the container are made with nozzles for the expiration of chemical reaction products and combustion from container when a fire-resistant cord and an aerosol-forming composition ignite. 24. A fire extinguisher delivery container according to any one of claims 14 to 20, characterized in that the container consists of detachable parts - head and cylindrical, in which the body of the cylindrical part is thermally destructive, filled with a powder fire extinguishing substance and has a sleeve at the junction with the head part with a through hole for filling with a fire extinguishing agent, connected to the head part with the overlapping of the through hole of the sleeve, while the head part contains a thermal explosion device. 25. A fire extinguisher delivery container according to any one of claims 14 to 20, characterized in that the container consists of parts - head and cylindrical, in which the cylindrical part is made with a heat-destroying body and has a threaded sleeve with a through hole, through a through hole is partially filled chemically active inhibitor under pressure and hermetically sealed with the installation of a threaded plug on the threaded sleeve, and the head part is screwed onto the external thread of the threaded plug and secured against the cylindrical part.

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