RU219239U1 - GAS FIRE EXTINGUISHING DEVICE - Google Patents

Abstract

The utility model relates to fire-fighting equipment and can be used in industrial and civil facilities, including those with increased fire hazard for localizing fires, as well as for effective fire extinguishing in rooms using automatic fire extinguishing systems. The gas fire-extinguishing device contains a container filled with a gas fire-extinguishing agent, with a locking nut and a shut-off and starting device. The lock nut is connected to the container outlet and contains a locking element that keeps the fire extinguishing agent inside the pressurized container. The shut-off and starting device consists of a housing for the pusher, on the one hand connected to the locking nut of the gas fire extinguishing device, and on the other hand connected to the sprayer. The housing for the pusher is a hollow rod with a mounting hollow base. In the lower part of the rod and partially in the mounting hollow base, coaxial grooves for the mounting pin are made. A pusher spring-loaded by a spring is fixed inside the rod, containing a mounting base and an elongated cylindrical tip truncated from the free end, on two surfaces of which flats are made. The mounting base has a through hole coaxial with said grooves, through which the pusher is fixed in a spring-loaded position through said grooves by means of a mounting pin. The atomizer is a hollow cylindrical cap, strung on the housing for the pusher and fixed through the holes in its lower part by means of the mentioned pin through the mentioned grooves and hole. A cavity is made in the upper part of the atomizer to accommodate a thermal lock. In the upper part of the atomizer, spray holes are made on the sides. The thermal lock forms a stop for said rod and prevents the spring from expanding. The destruction of the thermal lock leads to the decompression of the spring. Decompressing the spring causes said pin to move along said slots in the direction of the lock nut. The pusher is placed in such a way that, when the pin is moved, it moves in the direction of the lock nut, pierces the locking element of the lock nut and releases the extinguishing agent. The implementation of the assignment is provided. 2 ill.

Description

[0001] TECHNICAL FIELD

[0002] The utility model relates to fire-fighting equipment and can be used in industrial and civil facilities, including those with increased fire hazard for localizing fires, as well as for effective fire extinguishing in rooms using automatic fire extinguishing systems.

[0003] BACKGROUND

[0004] A device for extinguishing a fire is known, described in the application US2017036048A (D1). The known device for extinguishing a fire consists of a cylinder and a shut-off and starting device containing a thermal lock that is destroyed when the threshold temperature is reached, which actuates a spring-loaded pusher in the form of a hollow needle, which pierces the membrane of the cylinder and releases a gaseous fire extinguishing agent (GOTV) that exits under pressure through the nozzle holes.

[0005] The disadvantages of the device known from D1 are the complexity of manufacturing a pusher in the form of a hollow needle with coaxial cylindrical surfaces, as well as low reliability caused by involuntary sealing or narrowing of the passage channel of the needle by parts of the membrane or due to icing that occurs in the area of the passage channel through which mounting pin, and, as a result, a high probability of an increase in the exit time of the gas fire extinguishing agent.

[0006] UTILITY MODEL DISCLOSURE

[0007] The technical problems solved by the proposed technical solution are: 1) the creation of an easy-to-manufacture pusher in the form of a piercing needle for a shut-off device for a gas device for extinguishing a fire; and, as a result, the creation of an easy-to-manufacture (in comparison with analogues) shut-off and starting device for a fire extinguishing device; 2) creation of a pusher in the form of a piercing needle for a shut-off and starting device for a gas device for extinguishing a fire, which does not have a passage channel and is thus freed from the possibility of clogging the passage channel of the needle with parts of the membrane, freed from the possibility of narrowing the passage channel of the needle due to icing and, thus freed from the possibility of increasing the exit time of the extinguishing agent; and, as a result, the creation of a shut-off and starting device for a device for extinguishing a fire of increased reliability. Another technical problem solved by the proposed technical solution is the expansion of the arsenal of technical means for a specific purpose, namely, gas devices for extinguishing a fire with shut-off and starting devices based on the principle of piercing the membrane of a cylinder with a gas fire extinguishing agent.

[0008] The technical results achieved by implementing the proposed technical solution, in addition to realizing its purpose, are: 1) simplifying the design of the piercing needle of the pusher of the shut-off and starting device for a gas device for extinguishing a fire; and, as a consequence, reducing the complexity of its manufacture; and, as a consequence, reducing the complexity of manufacturing a shut-off and starting device for a fire extinguishing device as a whole; 2) exclusion of the possibility of blockage of the passage channel of the needle with parts of the membrane and the exclusion of the possibility of narrowing of the passage channel of the needle due to icing; and, as a result, increasing the reliability of the shut-off and starting device for the device for extinguishing a fire; and, as a result, increasing the reliability of the fire extinguishing device as a whole; and also, as a consequence, the exclusion of an increase in the time of the exit of the gas fire extinguishing agent.

[0009] The above technical results are achieved by the following set of essential features: a pusher for a shut-off and starting device for a gas fire extinguishing device, containing a mounting base configured to interact with the corresponding part of a shut-off and starting device for a gas fire extinguishing device, and an oblong truncated from the free the end face is a cylindrical tip, on two surfaces of which flats are made or a parallelepiped truncated from the free end.

[0010] BRIEF DESCRIPTION OF THE DRAWINGS

[0011] Exemplary embodiments of the claimed technical solution are described in detail below with reference to the accompanying drawings, which are incorporated herein by reference, and in which:

[0012] FIG. 1 shows an exemplary embodiment of a gas device for extinguishing a fire with a shut-off and starting device.

[0013] FIG. 2 shows an exemplary version of the pusher for the locking and starting device.

[0014] IMPLEMENTATION OF UTILITY MODEL

[0015] The possible implementations of the claimed technical solutions described in this section are presented on non-limiting examples of legal protection, in relation to specific embodiments of the claimed technical solution, which in all their aspects are assumed to be illustrative and not restrictive. Alternative options for implementing the claimed technical solution, which do not go beyond the scope of legal protection, are obvious to specialists in the field with the usual qualifications for which this technical solution is designed.

[0016] A suitable gas fire extinguishing device is any of the following: described in US2017036048A, the materials of which are hereby incorporated herein by reference; described in the patent of the Russian Federation No. 2667881, the materials of which, according to the application of the Russian Federation 2017135603 dated July 20, 2017, are thus included in this description by reference; as well as any other similar device, the principle of operation of which is based on the use of a shut-off device with a piercing needle to pierce the membrane of a cylinder with a gas fire extinguishing agent.

[0017] FIG. 1 shows an exemplary embodiment of a shut-off device 3 for the aforementioned gas fire extinguishing device 100. In general, the fire extinguishing device 100 is a container 1 filled with a gaseous extinguishing agent, with a lock nut 2, the lock nut 2 being connected to the outlet of the container and comprising a locking element retaining the extinguishing agent inside the pressurized container; and lock-start device 3, and lock-start device 3 consists of a housing 31 for the pusher, on the one hand connected to the lock nut 2, and on the other side connected to the sprayer 32; housing 31 for the pusher 4 is a hollow rod with a hollow mounting base 33, in the lower part of the rod and partially in the mounting hollow base 33, coaxial grooves 34 for the mounting pin 5 are made, while inside the rod a pusher 4 spring-loaded by a spring 37 is fixed, containing a mounting base 41 and an elongated cylindrical tip truncated from the free end 42, on two surfaces of which flats 421, 422 are made, and in the mounting base 41, a through hole 43 is made, coaxial with the mentioned grooves 34, through which, by means of the mounting pin 5, the pusher 4 is fixed in a spring-loaded position through mentioned grooves 34, moreover, the atomizer 32 is a hollow cylindrical cap, strung on the body 31 for the pusher 4 and fixed through the holes 35 in its lower part by means of the mentioned pin 5 through the mentioned grooves 34 and the hole 43, while in the upper part of the atomizer there is a cavity for location of the lock 6, while in the upper part of the atomizer on the sides there are spray holes 36, and the lock 6 forms a stop for the said rod and prevents the spring from expanding, and the destruction of the lock 6 leads to the expansion of the spring, and the expansion of the spring leads to the movement of the said pin 5 along the mentioned grooves 34 in the direction of the lock nut 2, and said pusher 4 is placed so that when the pin 5 moves in the direction of the lock nut 2, pierce the said locking element and release the fire extinguishing agent. At the same time, said lock 6 is a thermal lock, that is, as a rule, a glass flask containing a thermosensitive liquid, which, when a certain temperature is reached, expands, creating excess pressure inside the flask and leading to its destruction, or may be any other known (or created in the future) and a usable element capable of destruction, for example, but not limited to, when heated to a certain temperature, or in response to the detonation of an explosive inside the lock, or when the lock is mechanically acted upon, for example, but not limited to, when the lock is kinetically . Preferably, without limitation, the operating temperature of the lock 6 ranges from 57 to 93 +/- 3 degrees Celsius. At the same time, it should be obvious to a specialist in this field of technology, who has ordinary knowledge, for whom the claimed technical solution is designed, that another device can be used as a lock 6, for example, a metal rod or strip, the elasticity or fragility of which increases when heated. to certain temperatures, which will also lead to the termination of their action as a stop for the spring 37.

[0018] Preferably, but not limited to, container 1 may be a cylinder or any other container containing pressurized gas extinguishing agent. In this case, it is preferable that the volume of the container 10 be provided from 0.08 to 0.67 liters, the overall dimensions of the container 1 were, respectively, from 210 to 440 mm in length and from 35 to 60 mm in width, and the container 1 itself could accommodate , respectively, from 60 to 500 g of fire extinguishing agent. Such characteristics of the tank 1 make it possible to ensure sufficient manufacturability and safety of operation, since, in combination with other parameters of the device, the gas fire extinguishing agent is safely retained inside the tank 1. The gas fire extinguishing agent in this case is any suitable gas fire extinguishing agent, preferably, but not limited to, dioxide carbon, or, when the device is equipped with an adapter described below, another gas fire extinguishing agent, in particular, used with a propellant gas.

[0019] Preferably, but not limited to, the closure element may be, but not limited to, a metal membrane or a membrane of any other material capable of withstanding an operating pressure of 250 bar at 20 degrees Celsius. In this case, it is preferable, if the membrane is metallic, that its thickness is not less than 0.2 mm and not more than 1 mm. A person of ordinary skill in the art, for whom this technical solution is intended, should be obvious that if the membrane is made of a different material, it may need to have a different thickness, but still not lose the ability to withstand the specified operating pressure, and the pusher 4 should be able to break through such a membrane.

[0020] Preferably, without being limited, the grooves 34 in which the pin 5 moves are made symmetrically to each other in the walls of the housing 31 for the pusher 4. This allows the pusher 4 to be placed along the axis of the outlet of the container 11 and eliminates the possibility of it jamming or breaking through the locking element under wrong angle. Preferably, without being limited, the length of the grooves 34 in which the pin 5 moves, the length of the expansion of the spring 37, which ensures the movement of the pusher 4, approximately corresponds to half the length of the lock 6, which allows the pusher 4 to travel sufficient to reliably break through the locking element, but not block the spray holes 36 in the actuated state of the shut-off and trigger device 3. The pusher 4 (Fig. 2) contains a mounting base 41 and an elongated truncated cylindrical tip 42, on two surfaces of which flats 421, 422 are made, and a through hole is made in the mounting base 41 43, coaxial with said grooves 34, through which, by means of a fixing pin 5, the pusher 4 is fixed in a spring-loaded position through the mentioned grooves 34. Through the same pin 5, the pusher 4, the housing 31 for the pusher 4 and the atomizer 32 are fixed in relation to each other. Preferably, without limitation, the total cross-sectional area of the flats 421, 422 is selected to be greater than or at least equal to the cross-sectional area of the passage channel of the classic pusher known from patent application US2017036048A, the materials of which are incorporated herein by reference; or known from the patent of the Russian Federation No. 2667881, the materials of which according to the application of the Russian Federation 2017135603 dated 07/20/2017 are thus included in this description by reference. However, mainly it should be assumed that the total cross-sectional area of the flats 421, 422 is chosen such as to ensure the free exit of the fire extinguishing agent from the outlet along the flats 421, 422 in the direction of the inner walls of the spray cap 32 in the direction of the holes 36; that is, it should be mainly assumed that the radii of the flats 421, 422 are selected significantly less than the distance between the inner wall of the atomizer cap 32 and the outer wall of the housing 31 for the pusher 4. In this case, under the cross sections of the flats

421, 422, their radii are understood to be values calculated with respect to the cylinder in which these flats 421, 422 are made. In this case, the pusher 4 is preferably, without being limited, made of a cylindrical stainless steel rod by cutting off a cylinder of the required length from it and then in any order of performing the steps: performing a truncation from one of the ends, making a transverse hole 43 for the pin 5, performing from two of sides of flats 421, 422; which is a simpler and faster manufacturing method compared to the manufacturing process of a classic hollow needle pusher. At the same time, without limitation, a pusher 4 can also be provided, made of a cylindrical stainless steel rod by cutting off a cylinder of the required length from it and then in any order of performing the steps: partial or complete milling of the cylinder to obtain a workpiece for the pusher in the form of a parallelepiped, performing truncation of one of the ends of the parallelepiped, making a transverse hole 43 for the pin 5 from the other end; which is a simpler and faster manufacturing method compared to the manufacturing process of a classic hollow needle pusher, but more complicated than the above-described process for manufacturing a pusher with flats 421, 422, although it allows you to get a more efficient pusher in terms of overall dimensions, half-width dimensions the parallelepiped of which are preferably chosen to be substantially smaller compared to the distances between the inner wall of the atomizer cap 32 and the outer wall of the body 31 for the pusher 4. However, without being limited, if a suitable rectangular bar is provided, the manufacturing method can be reduced to cutting off the parallelepiped of the required length, making a transverse hole 43 for the pin 5 at one end and truncating the parallelepiped from the other end, which will further simplify and speed up the manufacturing process of the pusher 4. In the absence of a rectangular bar of the required dimensions, a milling step can also be provided to ensure the required dimensions of the parallelepiped. It should be obvious to a person of ordinary skill in the art, for whom this utility model is designed, that the pusher 4 can be made of the shapes and sizes described above from any other suitable material, the choice of which should mainly be based on that such a material should have a high melting point, as well as high hardness and low brittleness.

[0021] Preferably, but not limited to, the atomizer cap 32 may include multiple spray holes 36. In the case of two spray holes 36, it is preferable that such holes 36 are placed symmetrically to each other. In the case of three spray holes 36, it is preferable that such holes 36 were placed at an angle of 120 degrees with respect to each other. In the case of four spray holes 36, it is preferable that such holes 36 be placed at an angle of 90 degrees with respect to each other, and so on.

[0022] In order to be able to control the pressure inside the tank 1, it can be equipped with an adapter for a gas device 100 for extinguishing a fire, preferably, without being limited, made with the possibility of connection with the outlet of the tank 1 for a gaseous fire extinguishing agent, containing a passageway that is mated with the said outlet. a channel containing a branch connected to a fitting with a check valve, and the outlet of said passage channel is provided with a locking element, for example, without limitation, similar to that described earlier, and is configured to be connected to the shut-off and starting device 3 of the gas device 100 for extinguishing a fire, for example, without limitation, by means of a lock nut 2. Preferably, without limitation, at the junction of the branch and the fitting, the check valve is spring-loaded, which makes it possible to increase the reliability of filling the container 1, preventing accidental release of a fire extinguishing agent or gas. Preferably, but not limited to, the check valve is provided with a seal, such as, but not limited to, an O-ring. Preferably, but not limited to, the check valve has a cone-shaped part that extends into the cavity of the fitting. In this case, the fitting is configured to be connected to a pressure control device, for example, but not limited to, a pressure gauge or other unified device, such as a pressure indicator, an electrocontact pressure switch, an analog pressure sensor, and the like. This configuration of the adapter allows you to alternately fill the container 1 with different gases and/or fire extinguishing agents, for example, without limitation, it allows you to fill the container 1 first with a gas fire extinguishing agent - freon or a gas fire extinguishing agent based on fluoroketone, for example, without limitation, such as a gas fire extinguishing agent ZM ™ Novec™, and after the propellant - nitrogen. In addition, the use of the claimed adapter also allows the replacement of the fire extinguishing agent and/or gas in the tank without the need to disconnect the key elements of the fire extinguishing device - it is enough to remove the connected device, after which the fitting can be used as a drain and filling valve. The possibility of connecting a pressure control device allows you to constantly monitor the performance of the gas fire extinguishing device 100.

[0023] The claimed gas device 100 for extinguishing a fire is preferably, without limitation, placed in a protected volume to provide a method of protection against fire or a method of extinguishing a fire, in which the said device is activated either upon reaching the threshold temperature at which the lock 6 is activated, or forcibly by destroying the lock 6 by heating it, and/or detonating it, and/or by kinetic action in response to a signal from the control panel of the fire system, which, without being limited, is any fire system known from the prior art, which, accordingly, is not further detailed described. Preferably, without being limited, the volume to be protected is some small-sized closed volume, such as, for example, without limitation, a closed distribution and / or power and / or input mounting board, a stationary access and / or floor electrical panel, internal and /or an outdoor electrical cabinet, a mounted and/or built-in electrical panel and/or an electrical box, a mounted and/or built-in control panel, a server rack with equipment, a telecommunications rack with equipment, a vehicle engine compartment, a space for placing electric energy batteries in a vehicle, the cargo compartment of the vehicle and the like volumes. In this case, without being limited, it should be mainly assumed that the volume to be protected is predominantly a closed volume, since in this case the efficiency of gas fire extinguishing is the highest. However, it should be obvious to a person of ordinary skill in the art, for whom this utility model is designed, that the volume to be protected can be any volume in which a sufficient number of the claimed gas devices 100 for extinguishing a fire are placed, the total power of which allows to displace air mass from the protected volume, thereby depriving the ignition source of access to oxygen.

[0024] This description of the claimed technical solution demonstrates only private embodiments and does not limit other options for its implementation, since possible other alternative embodiments that do not go beyond the scope of the information set forth in this application should be obvious to a person skilled in the art, having the usual qualifications for which the claimed technical solution is designed.

Claims (1)

A gas fire extinguishing device containing a container filled with a gas fire extinguishing agent, with a lock nut, the lock nut being connected to the outlet of the container and containing a locking element that holds the fire extinguishing agent inside the container under pressure, and containing a shut-off and starting device (LPU), consisting of a housing for a pusher, on the one hand connected to the locking nut of the gas fire extinguishing device, and on the other hand connected to the atomizer; the housing for the pusher is a hollow rod with a mounting hollow base, in the lower part of the rod and partially in the mounting hollow base, coaxial grooves for the mounting pin are made, while inside the rod a spring-loaded pusher is fixed, containing the mounting base and an elongated cylindrical tip truncated from the free end, on two surfaces of which flats are made, and in the mounting base a through hole is made, coaxial with the mentioned grooves, through which the pusher is fixed in a spring-loaded position through the mentioned grooves by means of the mounting pin, and the atomizer is a hollow cylindrical cap, strung on the body for the pusher and fixed through openings in its lower part by means of said pin through said grooves and hole, while in the upper part of the atomizer there is a cavity for accommodating a thermal lock, while in the upper part of the atomizer, spray holes are made on the sides, and the thermal lock forms a stop for the said rod and prevents expansion springs, and the destruction of the thermal lock leads to the expansion of the spring, and the expansion of the spring leads to the movement of the said pin along the said grooves in the direction of the lock nut, and the said pusher is placed in such a way that, when the pin moves, it moves in the direction of the lock nut, punches the locking element of the lock nut and release the extinguishing agent.

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