RU228582U1 - Gas powder fire extinguishing device - Google Patents

Abstract

The utility model relates to the field of fire extinguishing. The gas-powder fire extinguishing device contains a metal frame made of a 2 mm thick profile, closed from the outside with a casing. A cylinder with a powder substance, connected to a branch pipe for releasing a gas-powder mixture into the environment, a cylinder with high-pressure gas, through a shut-off and starting unit, connected to the cylinder with the powder substance, are fixed to the frame, wherein the outlet of the shut-off and starting unit is connected through a metal tube to the cavity of the cylinder with the powder substance, the outlet of which is sealed with a rupturable membrane. In order to accommodate two cylinders with a total capacity of 10 l, the frame is made in the form of a closed perimeter frame with two side vertically oriented posts connected to each other by crossbars to form a closed contour, inside which there are crossbars spaced apart along the height of the posts in the form of plates with openings used to fasten the ends of the clamps when securing the cylinders on the two upper crossbars, and supports secured in openings on the two lower crossbars used to accommodate the bottom parts of the cylinders and having mating elements for fastening the ends of the clamps on the side walls of these supports. In the upper part of the frame, in the area between the upper crossbar of the frame and the upper crossbar, a solid metal sheet with openings for fastenings when hanging on a vertical support surface is attached to the frame elements, and a solid sheet with bends along the perimeter is attached to the lower crossbar of the frame transversely to the posts, on which corner elements are fixed, attached to the posts. 2 ill.

Description

The utility model relates to the field of fire extinguishing and concerns the design of a gas-powder fire extinguishing device with a useful volume of 10 liters, both wall-mounted and floor-mounted, used as a means of extinguishing a fire in a closed volume or a conditionally sealed room in a volume limited by walls, by enveloping the fire zone with a gas-powder mixture.

In particular, the present application considers the design of a device made with either an automatic initiation function or a remote control signal function for initiating a chemical reaction process for the purpose of forming a gas-powder extinguishing cloud directed to the area of the fire or covering the area of the fire. In particular, the application considers a device used for placement on one wall of a room for the purpose of supplying a gas-powder extinguishing medium in the direction of the opposite wall.

The modern development of society in terms of the development and complication of social infrastructures leads to an increase in man-made consequences caused by technical failures, human factors and natural phenomena.

Dependence on man-made consequences has caused the need to create means that allow extinguishing a fire at the initial stage of its development without human intervention. For this purpose, gas-powder fire extinguishers were created in the form of containers and cylinders fixed to the ceiling of the room or to its walls, containing chemical separately stored agents, when combined, a reaction occurs with the release of a gas extinguishing composition, sprayed throughout the volume of the room.

Thus, a powder-type fire extinguishing device is known, comprising a cylinder with a baffle cap and fire extinguishing powder, a shut-off and starting unit, a cylinder with gas under pressure, a means for supplying gas at a gas and powder mass ratio of 1:0.2 - 1:7, carrying an outlet nozzle at the end, the gas source is connected through a siphon tube with a flow section constituting 0.05 - 0.2 of the flow section area of the outlet nozzle, fixed in the baffle cap, with the cavity of the cylinder with fire extinguishing powder, wherein the lower end of the siphon tube is located at a distance from the bottom of the powder body of no more than 1/10 and no less than 1/50 of the height of the poured fire extinguishing powder, and the outlet nozzle is made in the form of a perforated pipe with a cap that hermetically closes the perforation and is calibrated with a shear pin, wherein the ratio of the perforation areas and the flow section the outlet nozzle is 0.3 - 0.8 (RU 2193427, A62C 13/66, published on 27.11.2002).

This solution was adopted as a prototype.

Structurally, the device includes two cylinders located at a distance from each other and connected by a metal tube. In essence, this device is a fire extinguisher with separate storage of gas and powder, the connection of which occurs after the operation of the manual control shut-off and starting unit.

The patent presents a design scheme for a device that falls into the category of separate storage, i.e. a cylinder with gas under pressure, for example, 16 atm, is located separately from a cylinder with powder, in which the pressure is equal to atmospheric. Such separate cylinders are difficult and unsafe to carry. When storing components separately, the device is transferred to the category of dangerous for human use due to the high pressure in one of the cylinders.

The peculiarity of the prototype solution is that both cylinders in the device must be clearly positioned relative to each other as a single inseparable structure. This is explained by the fact that both cylinders are connected to each other by a metal tube, through which gas under pressure enters the cylinder with powder. Breakage of this tube will lead to the inoperability of the device. But the tube itself is not a power element that can hold both cylinders. It is simply a coupling screwed into both cylinders. In this regard, both cylinders with such a connection scheme must fit tightly to each other. But even in this case, there is a high probability of incorrect positioning of the coupling (skew), which can lead to a violation of the threaded connections, which leads to a depressurization of the connection when gas is released into the cylinder with powder.

The known device does not belong to manual ones, the design indicates that these cylinders should be attached to the frame. For example, the weight of a large cylinder is 8 kg, and the weight of the powder contents in this cylinder is 6.7 kg. The weight of the expelling gas in a small cylinder is 3.1 kg with the weight of the cylinder itself being 5 kg. In total, the device without the shut-off and starting unit, communication unit and tubes is approximately 17-18 kg. Consequently, these cylinders and their associated units should be attached to a separate frame, which should accurately position the connecting tube between the cylinders.

The well-known patent does not mention the presence of a frame or framework. At the same time, there is no information about what kind of device is being discussed: a floor-mounted device or a wall-mounted device.

This utility model is aimed at achieving a technical result consisting in increasing operational safety by fastening cylinders spaced apart and connected by a metal tube from each other on a landing frame, which can be fixed both to the wall and to the floor of the room.

The specified technical result is achieved in that the gas-powder fire extinguishing device contains a metal frame made of a 2 mm thick profile, closed from the outside by a casing, on which a cylinder with a powder substance is fixed, communicated with a branch pipe for releasing a gas-powder mixture into the environment, a cylinder with high-pressure gas, through a shut-off and starting unit, communicated with the cylinder with the powder substance, wherein the outlet of the shut-off and starting unit is communicated through a metal tube with the cavity of the cylinder with the powder substance, the outlet of which is sealed with a rupturable membrane, for placing two cylinders with a total capacity of 10 liters, the frame is made in the form of a frame closed along the perimeter with two side vertically oriented posts connected to each other by jumpers to form a closed circuit, inside which there are crossbars in the form of plates with openings spaced apart along the height of the posts, used for fastening the ends of the clamps when fastening the cylinders on the two upper crossbars, and lodgements fixed in openings on the two lower crossbars used to accommodate the bottom parts of the cylinders and having mating elements for securing the ends of the clamps on the side walls of these supports, and the shut-off and starting unit and the metal tube are brought out into the area of the upper part of the frame above the upper crossbar, while in the upper part of the frame in the area between the upper crossbar of the frame and the upper crossbar a solid metal sheet with openings for fastenings when hanging on a vertical support surface is placed, attached to the elements of the frame, and a solid sheet with bends along the perimeter is attached transversely to the posts to the lower crossbar of the frame, on which corner elements are secured, attached to the posts.

The specified features are essential and are interconnected with the formation of a stable set of essential features sufficient to obtain the required technical result.

This utility model is illustrated by a specific example of implementation, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result.

Fig. 1 - general view of a gas-powder fire extinguishing device enclosed in a casing;

Fig. 2 - placement of the gas-powder fire extinguishing device on a separate frame, the casing is dismantled.

According to this utility model, the design of a gas-powder fire extinguishing device is considered, which can be used both in a wall-mounted version and in a floor-mounted version.

The device in the form of a ready-made and self-functioning gas-powder fire extinguishing product can be made with automatic initiation of a chemical reaction or with initiation in the mode of remote sending of a control signal to start the chemical process. This indicates that the fire extinguishing process begins either without human participation or with his participation at a distance from the source of fire. For example, a remote initiation button can be brought out to the wall of the room or to another room or made with the function of triggering from a remote control.

In general, the design of the declared utility model is as follows:

- a metal frame closed from the outside with a casing is made of a 2 mm thick profile and is used to accommodate two cylinders with a total capacity of 10 liters;

- a cylinder with a powder substance is fixed to the frame, connected to the branch pipe for releasing the gas-powder mixture into the environment, a cylinder with high-pressure gas, through a shut-off and starting unit, connected to the cylinder with the powder substance, while the outlet of the shut-off and starting unit is connected through a metal tube to the cavity of the cylinder with the powder substance, the outlet of which is sealed with a rupturable membrane;

- the frame is made in the form of a closed perimeter frame with two side vertically oriented posts connected to each other by crossbars to form a closed circuit, inside which there are crossbars spaced apart along the height of the posts in the form of plates with openings used to secure the ends of the clamps when securing the cylinders on the two upper crossbars, and supports secured in openings on the two lower crossbars used to place the bottom parts of the cylinders and having mating elements for securing the ends of the clamps on the side walls of these supports;

- in the upper part of the frame, in the area between the upper frame crossbar and the upper crossbar, a solid metal sheet with holes for fastenings when hanging on a vertical support surface is attached to the frame elements, and a solid sheet with bends along the perimeter is attached transversely to the posts to the lower frame crossbar, on which corner elements are fixed, attached to the posts;

- the shut-off and starting unit and the metal tube are brought out into the area of the upper part of the frame above the upper crossbar.

Below is a description of a specific example of implementation with reference to Figs. 1 and 2.

The device in question consists of two cylinders with a total capacity of 10 liters (volume) - separate storage mode for components.

In general, the device consists of a frame 1 (Fig. 2), which is hung on a vertical support surface of the room or installed on the floor of the room and in which the elements of the gas-powder fire extinguishing units are fixed, and a casing 2 (Fig. 1) of a parallelepiped shape, which is put on the frame with its girth.

The casing 2 is made in the form of a box made of thin-walled material (polymer or metal sheet) that is open on one side and does not bear a power load, it performs the function of protecting the module from the effects of the external environment and restricting unauthorized access to the cylinder placement area. In the upper end wall of the casing 2 there are two openings 3 and 4: the first opening 3 is intended for the output of the tube 5 of the gas-powder mixture release channel (it may have a sprayer 6 at the end), and the second 4 is used to input wires into the casing. Both openings are sealed with rubber seals 7

Frame 1 is made of steel and has holes 8 on the rear wall, which is solid in the upper part, for passing fasteners for attaching it to the supporting surface (for hanging on a wall). In the considered version, the frame is made of metal corner elements (profile) with a wall thickness of 2 mm. The plates - crossbars are also made 2 mm thick. If we compare the same frame made of a standard metal profile with a wall thickness of 3 mm, then the gain in the new frame will be approximately 15 kg. For the hanging version of the device installation, such a gain in weight is significant, since it becomes possible to increase the reliability of hanging the assembled device on the wall.

As shown in Fig. 2, the gas-powder fire extinguishing device includes a cylinder 9 with a powder substance (in the form of a container for placing powder weighing 6.7±0.3 kg), communicated with a tube 5 for releasing the gas-powder mixture into the environment. A shut-off and starting unit 11 is screwed onto the cylinder 10 with high-pressure gas (in the form of a container for placing the applied working gas (carbon dioxide) weighing 3.1±0.1 kg), which is communicated with the cavity of the cylinder 9 with the powder substance through a metal tube 12 having a thread at the ends for hermetically screwing into the wall (nose) of the cylinder 9 and into the outlet channel of the unit 11. A siphon tube can be located in the cavity of the cylinder 9, extended from the opening in the wall of the cylinder for the tube 11 to the bottom of the cylinder.

The outlet of the high-pressure gas cylinder 10 is connected to a separate shut-off and starting unit 11, one end of which is screwed into the spout of this cylinder and is positioned by this cylinder as its continuation. Structurally, the shut-off and starting unit 11 consists of a housing, inside which a hollow bushing is placed, pressed by a spring away from the rupturable membrane, which seals the cavity of the cylinder 10 from communication with the cavity of the cylinder 9. A transverse channel is made in the housing of the unit, in which a pyrotechnic element 13 is placed, and the outlet part of this channel is connected to the control cavity of the hollow bushing. The pyrotechnic element 13 is made with contact wires, which are connected to contact groups in the communication block 14, which is made explosion-proof.

The input contact group of the communication unit 14 is intended for connection either to a temperature sensor or a gas-analyzing sensor, which can function as initiators of the issuance of a control signal to the pyrotechnic element for its detonation, or to a wired communication system with a remotely located button, pressing which ensures the issuance of a control signal to the pyrotechnic element for its detonation. Upon receipt of the signal, the pyrotechnic element is detonated, the gas pressure from which enters the control cavity of the hollow bushing and, overcoming the force of the spring compression, shifts the bushing towards the membrane and breaks through it, ensuring the passage of the gas flow through the cavity of the bushing to the exit from the housing and into the bellows tube.

Both cylinders are located at some distance from each other, excluding contact of the walls. This requirement is due to the fact that each cylinder contains a substance whose properties do not match the properties of the substance in the other cylinder. For example, when using liquefied carbon dioxide for cylinder 10 and its entry into the bellows tube, a temperature transformation occurs, leading to a decrease in temperature to -70 ° C. And when heated by the environment (under the influence of ultraviolet light or high room temperature), this liquefied gas begins to expand, increasing the internal pressure in the cylinder.

Frame 1 is made in the form of a closed perimeter frame with upper and lower crossbars 15, connecting two side vertically oriented posts 16, thereby forming a closed frame contour. Posts 16 are connected to each other by crossbars spaced apart along the height of the posts in the form of plates 17-20 with openings 21, used for fastening the ends of clamps 22 when securing cylinders on two upper crossbars 17 and 18, and by supports 23, fastened in openings on two lower crossbars 19 and 20, used for placing the bottom parts of cylinders 9 and 10 and having mating elements for fastening the ends of the clamps on the side walls of these supports. The upper part of the frame, located between the upper crossbar 15 and the upper crossbar 17, is closed by a solid metal sheet 24 (openings 8 are made in this sheet). In the upper part of the frame, under the upper crossbar 15 (and above the upper crossbar 17), a space is formed for placing the shut-off and starting unit 11, the switching unit 14 and the metal tube 12.

The frame posts and the crossbars connecting them are made in an angular shape in cross-section, and the crossbars 171-20 are made of plates with edges bent along the length of the plates, which ensures spatial retention of the frame shape.

The use of crossbars at different frame heights is due to the fact that the cylinders are made of different lengths, which requires elements for attaching clamps at different frame heights.

Such a frame allows for the precise fixing of cylinders and the elements of the block diagram associated with them in a precise coordinate position, eliminating the load on the metal tube 6. The frame is made on racks with elements for attaching a box-type casing, which is a cover for closing the cylinders.

Such a frame maintains the flatness of the structure, but is subject to torsion. To eliminate bending, a solid wall in the form of a metal sheet located in the upper part of the frame and connected to the upper crossbar 15 is introduced into the frame design. This sheet functions as a stiffening element, eliminating deformation of the frame in the plane of the suspension by eliminating deformations in the corner zones at the junction of the upper crossbar with the posts.

As an option, this sheet can also be connected to the upper crossbar 17. This will increase the strength of the frame in terms of the bending category. The issue of eliminating frame deformation is related to the fact that the hanging of cylinders with associated units is not balanced. So, on one half of the frame there is a large cylinder with powder weighing approximately 14-15, and on the other half of the frame there is a small cylinder weighing approximately 8-9 kg. This leads to the appearance of an overturning moment or bending moment on the frame acting towards the rack from the side of the large cylinder. In fact, the frame refers to frames with an unbalanced load. Such moments lead to frame deformation, which manifests itself in the form of deformation of the corner zones between the upper crossbar 15 and racks 16. This is explained by the fact that a reduced thickness profile is used for the frame. This is important for the case of floor placement of the device. When hanging on a wall, the same thing happens, despite the fact that the frame is mounted on two horizontally spaced fasteners. In this case, the frame is deformed due to the fact that one of the fasteners is overloaded and the other is underloaded, which leads to weakening of the fastener.

Since the frame 1 is used both for the wall hanging option and for placing it on the floor of the room, means are provided for holding the frame on a horizontal surface. A transversely located plate 25, made with side bends, is attached to the lower crossbar 15 of the frame. Corners 26 are fixed to this plate, screwed on one side to the plate 25, and on the other side attached to the posts 16. These corners position the frame in a perpendicular position relative to the plate 25, which acquires the function of supporting the floor of the room and does not allow the frame to tip forward under the weight of the cantilever-mounted cylinders. In this case, this plate together with the corners is a stiffening element for the lower part of the frame, performing the same function as the plate 24 in the upper zone of the frame. In addition, the side bends of plate 25 are used as elements for positioning and attaching the walls of casing 2. Plate 25 is functional for the frame, regardless of the option of its location: on the wall or on the floor.

This utility model is industrially applicable and can be repeated many times. The utility model allows to increase the operational safety of the device due to the new frame design and its implementation with the possibility of hanging on a wall or placing on the floor.

Claims (1)

A gas-powder fire extinguishing device characterized in that it contains a metal frame made of a 2 mm thick profile, closed from the outside with a casing, on which a cylinder with a powder substance is fixed, communicated with a branch pipe for releasing a gas-powder mixture into the environment, a cylinder with high-pressure gas, through a shut-off and starting unit, communicated with the cylinder with the powder substance, wherein the outlet of the shut-off and starting unit is communicated through a metal tube with the cavity of the cylinder with the powder substance, the outlet of which is sealed with a rupturable membrane, for placing two cylinders with a total capacity of 10 liters, the frame is made in the form of a frame closed along the perimeter with two side vertically oriented posts connected to each other by jumpers to form a closed circuit, inside which crossbars in the form of plates with openings are located spaced apart along the height of the posts, used for fastening the ends of the clamps when fastening the cylinders on the two upper crossbars, and lodgements fixed in the openings on two lower crossbars used for placing the bottom parts of the cylinders and having mating elements for securing the ends of the clamps on the side walls of these supports, and the shut-off and starting unit and the metal tube are brought out into the area of the upper part of the frame above the upper crossbar, while in the upper part of the frame in the area between the upper crossbar of the frame and the upper crossbar a solid metal sheet with holes for fastenings when hanging on a vertical support surface is placed, attached to the elements of the frame, and a solid sheet with bends along the perimeter is attached transversely to the posts to the lower crossbar of the frame, on which corner elements are secured, attached to the posts.

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