RU214471U1 - Gas-powder fire extinguishing device for a closed room - Google Patents

Abstract

Useful, the model belongs to the field of firefighting. The gas-powder fire extinguishing device for a closed room contains a gas-powder fire extinguishing module placed in a housing, on which a suspension is fixed for attaching to the elements of the ceiling part of the room. The body is made of thin-sheet material in the form of an octagonal prism with side faces located along the length of the body, one end of which is blind, and the other end is closed by a perforated partition, behind which a transverse flat partition is placed in the body. The points of attachment of the suspension to the body are displaced along the length of the body towards the blind end to position the body in a suspended state at an angle to the floor of the room. The gas-powder fire extinguishing module includes two side-by-side high-pressure cylinders with reagents for obtaining a gas-powder medium, each of which is connected through a separate shut-off and start-up unit with a branch pipe for the outlet of the gas-extinguishing medium, common for both cylinders, brought out of the body through a flat transverse and perforated partition. Supports are mounted in the housing for fixing the cylinders obliquely towards the lower wall of the housing at the indicated partitions at an angle to the longitudinal axis of the housing and a support for fixing the branch pipe of the gas-powder medium outlet in the upper part of the housing near the indicated partitions. Each shut-off and starting unit is made with a movable element used to pierce the membrane that isolates the cylinder cavity from the external environment, and with a pyrotechnic element for generating gas pressure to displace the movable element towards the membrane. The wires of the pyrotechnic elements are connected to a communication block used to communicate with the power supply of these pyrotechnic elements. 3 ill.

Description

The utility model relates to the field of fire extinguishing and concerns the design of a gas-powder fire extinguishing module used as a means of extinguishing a fire in a closed volume or in a volume bounded by walls by enveloping the fire source with a gas-powder mixture, excluding oxygen access to this source.

In particular, within the framework of the present application, the design of a module is considered, made with the function of either automatic initiation or with the function of remotely supplying a control signal for initiating a chemical reaction process in order to form a gas-powder quenching cloud directed into the fire area or covering the fire area. In particular, a module is considered that is used to be placed on the ceiling or beam of a room in order to supply a gas-powder extinguishing medium from the ceiling to the floor of the room.

Gas-powder fire extinguishing modules, despite the commonality with fire extinguishers of manual initiation by moving the lever in the use of propellant gas and powder, differ in that the initiation of the start of a chemical reaction occurs either fully automatically or by pressing a remotely located button. The release of a gas-powder cloud occurs almost instantly and because of this in a volume covering almost the entire vehicle. This results in fast and reliable fire extinguishing. Another feature is that the creation of a large-scale gas-powder flame-extinguishing cloud does not depend on the volume of chemical reagents, but depends on the gas release rate, which is equated to the reaction rate of these chemical reagents. This allows you to significantly reduce the weight of the fire extinguishing module, as well as the weight of its body.

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 equipment failures, the human factor and natural phenomena. For example, the abundance of electronic equipment, expanded lighting of premises, the use of automation systems for some works leads to the need for a serious expansion. electrical wiring in the room to provide power to all consumers in this room. Mistakes in the design of electrical wiring or an overload of the electrical network in a room can lead to a fire in a confined space, which cannot be immediately visually determined from the outside.

Dependence on man-caused consequences necessitated the creation of tools that allow, with or without human participation, to extinguish the fire at the initial stage of its development. For this purpose, gas-powder fire extinguishers were created in the form of containers and cylinders fixed on the ceiling of the room or on its walls, containing separately stored chemical agents, when combined, a reaction occurs with the release of a gas extinguishing composition sprayed throughout the room. In this case, the beginning of a chemical reaction can be initiated both by the person himself, and provided by the mode of automatic start of the process by a control signal received, for example, from a room temperature sensor or a gas-analyzing type sensor.

Traditionally, all fire extinguishers, regardless of the external form and internal design, were painted red. An example would be any fire extinguisher. On the one hand, this color is used as the “shape” of this type of device, and on the other hand, it is intended for the quick detection of a fire extinguisher in case of a fire. When it comes to small fire extinguishers, the consumer or the buyer or the person in the room perceives this device as a necessary element of the interior or furnishings, which always catches the eye. Everyone is used to this and something red and oblong in the corner of the room does not cause dissonance in understanding why it is here. But a red-painted fire extinguishing cylinder on the ceiling in any room does not and cannot fit into the interior of any office or apartment (an example of the oval-shaped module case is described in utility models RU 28622 and RU 50841). The problem also lies in the fact that with an increase in the dimensions of industrial powder fire extinguishing modules (in order to increase the volume of gas output and the area of extinguishing), such devices as functional systems sometimes cause an internal feeling of increased danger emanating from the place where a person or worker is located. and this system. The impact is purely psychological, but if it has already manifested itself, it remains on the subconscious and this prevents the employee from performing his functions. The feeling of self-preservation as a result of understanding the possible danger has a negative effect on the employee and on the staff as a whole. And this despite the fact that the powder fire extinguishing modules do not require the participation of the employees themselves in their work: the module is triggered automatically and beyond the desire of the employees.

There have been attempts to hide fire extinguishers in casings that do not directly indicate the presence of fire extinguishers in them. For example, in the patent document JP 2002282376, A62C 13/76, publ. 10/02/2002, a casing is described in the form of a bag with a handle in which a fire extinguisher is stored, or in the form of a cap worn on top of a fire extinguisher. And in US 2805724, A62C 13/78, publ. On September 10, 1957, a mesh-lined tubular casing with a door, hung on a wall and inside of which a fire extinguisher is placed, is described. And in RU 201144, A62C 8/00, A62C 13/00, publ. On November 30, 2020, the fire extinguisher was placed in a housing, made in the form of objects of the natural environment that attract people's attention (in the form of an apple or pineapple, strawberry or pumpkin, etc.), while the trigger parts of the fire extinguisher are specially brought out of the housing. These attempts to hide the fire extinguisher are not well resolved from a design standpoint.

An analysis of the prior art shows that the issue of covert storage of powder fire extinguishing modules that have the ability to operate automatically without human intervention remains unresolved and psychologically in demand in the conditions of the need to constantly locate fire extinguishing devices in areas of closed volumes.

Thus, a powder fire extinguishing device, hung on the ceiling, is known, which is described in the patent for prom. sample No. 50088, 29-01, publ. 03/16/2002 This decision was made as a prototype.

This device contains a housing suspended from the ceiling in the form of a cylinder, coupled with hemispheres, which form the bottom and top. The fixing device for fastening the module to the ceiling is made in the form of a bowl in the form of a hemisphere with a flange. In the case, a nozzle-sprayer is mounted in the form of an located one. in the center of the bottom of a U-shaped perforated head with a diameter much smaller than the diameter of the bottom. A toroidal fluorescent lamp is fixed around the body, which gives the module the appearance of a pendant lamp.

The camouflage actions in this solution are cosmetic in nature and, in fact, do not mask the module, but give it the appearance of a strange lamp. True, there is one advantage here. When the fluorescent lamp is turned on, a cloud of bright glow is created, behind which the device itself is not visible.

In this device, the reagents that form the gas-powder medium are placed in the housing in a small amount, which makes it possible to obtain a small output of the medium, sufficient only for a small enclosed space. After that, the device is disposed of, since its design does not allow the case to be reused. The device cannot be increased in size by the type of similarity in order to cover a larger area of the room, since this is associated with an increase in its weight and with the loss of such a property as disguising the device as a lamp. With an increase in the size of the housing, not only the geometry changes, but also the design of the module as a fire extinguishing device, including the issue of its strength. In this case, it can no longer be considered as a pendant lamp.

This utility model is aimed at achieving a technical result, which consists in increasing the operational reliability of a device suspended from the ceiling, in the body of which a gas-powder fire extinguishing module is placed with automatic initiation or initiation in a remote mode by using the layout of an inclined arrangement of high-pressure cylinders and changing the structure of their support inside the body .

The specified technical result is achieved by the fact that the gas-powder fire extinguishing device for a closed room contains a gas-powder fire extinguishing module placed in a housing on which a suspension is fixed for attaching to the elements of the ceiling part of the room, the housing is made of thin sheet corrosion-resistant material of an octagonal shape in cross section in the form of an octagonal prisms with side faces located along the length of the body, one end of which is blind, and the other end is closed by a perforated partition, behind which a transverse flat partition is placed in the body, the points of attachment of the suspension to the body are displaced along the length of the body towards the blind end to position the body in a suspended in a state inclined to the floor of the room, the gas-powder fire extinguishing module includes two adjacent high-pressure cylinders with reagents for obtaining a gas-powder medium, each of which is connected through a separate shut-off and start-up unit with a common for both cylinders brought out of the body through a flat transverse and perforated partitions with a branch pipe for the exit of gas-extinguishing medium, while supports are mounted in the body for fixing the cylinders obliquely towards the lower wall of the body at these partitions at an angle to the longitudinal axis of the body and a support for fixing the branch pipe for the outlet of the gas-powder medium in the upper part of the housing at the specified partitions, each shut-off and starting unit is made with a movable element used. to pierce the membrane that isolates the cavity of the cylinder from the external environment, and with a pyrotechnic element for generating gas pressure to shift the movable element towards the membrane, and the wires of the pyrotechnic elements are enclosed in rigid tubular guides and connected to the communication unit used for communication with the power supply, mounted on these tubular guides.

These features are essential and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

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

Fig. 1 is a general view of a gas-powder fire extinguishing device in a 3/4 view;

fig. 2 - longitudinal section of the shut-off and starting unit;

fig. 3 - the layout of the gas-powder fire extinguishing module inside the housing.

According to this utility model, the design of a gas-powder fire extinguishing device is considered, made in the form of a camouflage spotlight with a powder fire extinguishing module placed inside it 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. The device is designed to be suspended from a ceiling or ceiling beam. This indicates that the fire extinguishing process begins either without the participation of a person or with his participation at a distance from the source of ignition. For example, a remote initiation button can be placed on the wall of a room or in another room, or made with the function of being triggered by a remote control.

In the system of the human environment in which he works or rests, there is always a large number of functional devices with an explicit or implicit design in terms of emphasizing this functionality. Such devices include ATMs, terminals, various columns and panels of information support, etc. In everyday life, these devices, as a rule, are in the background of visual accessibility, if a person has a target direction in the foreground, and are taken for granted in terms of functionality, if this device is in demand as a target direction. In other words, on the way to work, a person does not pay attention to the terminals put up on the walls or in the corners, does not see their direct purpose, for him these are just elements of the route design. And only if it is necessary to make a payment, these terminals acquire material tangibility and then a person clearly evaluates these terminals and chooses the one that he needs. This is the psychology of human behavior in a developed social infrastructure.

This principle of psychological assessment of the situation, according to which “what is not important is not visible”, allows a person not to overload his consciousness with an abundance of information, most of which does not currently correspond to his target movement. But it does allow the designer to manipulate the appearance of the object in order to bring it visually to the fore or make it visually non-dominant. For example, you can fix a red switch on a white wall, which will allow it to be seen and seen in any cases (attention point), or you can fix a white switch on a white wall, which acquires stealth and requires increased care to detect it.

Within the framework of the present application, these psychological features of the perception of the external environment by a person underlie the formation of the masking part of a ceiling-type gas-powder fire extinguishing device.

In the general case, the constructive algorithm of the claimed utility model is a gas-powder fire extinguishing device. for ceiling hanging, formulated as follows:

contains a gas-powder fire extinguishing module placed in a housing, on which a suspension is fixed for attaching to the elements of the ceiling part of the room with the location of the attachment points of the suspension to the housing offset along the length of the housing towards the blind end to position the housing in a suspended state obliquely to the floor of the room;

the body is made of thin-sheet corrosion-resistant material of octagonal shape in cross section in the form of an octagonal prism with side faces located along the length of the body, one end of which is blind, and the other end is closed by a perforated partition, behind which a transverse flat partition is placed in the body;

the gas-powder fire extinguishing module includes two side-by-side high-pressure cylinders with reagents for obtaining a gas-powder medium, each of which is connected through a separate shut-off and start-up unit with a gas-powder medium exit pipe common for both cylinders, brought out of the body through a flat transverse and perforated partition;

supports are mounted in the housing for fixing the cylinders obliquely towards the lower wall of the housing at the specified partitions at an angle to the longitudinal axis of the housing and a support for fixing the outlet pipe of the gas-powder medium in the upper part of the housing at the specified partitions;

each shut-off and starting unit is made with a movable element used to pierce the membrane that isolates the cavity of the cylinder from the external environment, and with a pyrotechnic element for generating gas pressure to shift the movable element towards the membrane;

the wires of the pyrotechnic elements are enclosed in rigid tubular guides and connected to a communication unit used for communication with the power supply, fixed on these tubular guides.

Below is a description of a specific example of the claimed utility model with reference to FIG. 1-3.

The device under consideration compositionally consists of a housing 1 (Fig. 1) and a gas-powder fire extinguishing module (Fig. 3).

Gas-powder fire extinguishing module. consists of two cylinders 3 of an elongated cylindrical shape located side by side on supports fixed in the body. The red cylinders contain propellant gas and powder. When the system for detecting signs accompanying a fire is triggered, the gas combines with a powdered substance, leading to a chemical reaction, accompanied by the formation of a gas-powder cloud emitted into the environment (indoors), isolating the source of ignition from compounds with oxygen from the air.

It is proposed to place this functionality in a special case with flat walls and constant thickness. The essence of the choice of such a concept is based on giving the module the form of a suspended searchlight lantern that is familiar to perception.

The body 1, elongated along the length, is made of an octagonal shape in cross section. The housing made of thin-sheet corrosion-resistant material bears a suspension 4 (attachment element to a beam or ceiling). The case has the shape of an octagonal prism with a changed proportion of the widths of the faces. Structurally, such a three-dimensional body has eight side faces, each second of which is smaller in width than the adjacent one. All narrow side faces are made of the same width, all wide side faces are also made of the same width. One end is closed with a lid and is deaf. And the other end of the prism is made open, a perforated partition 5 is inserted into it, through which the gaseous cloud is released into the room. Partition 5 is located recessed in the housing cavity (located obliquely). In the upper part of the partition, one of the perforations is larger than the others and is a technological opening for the exit of the gas-powder medium. Opposite this opening is a branch pipe 6 for ejection of a fire extinguishing agent. Behind the perforation partition, at a short distance from it, there is a blank wall, which is also a flat transverse partition, isolating the powder-type module from being able to see it. The branch pipe 6 for ejection of the fire-extinguishing agent passes through this blind flat partition, but does not reach the perforated partition.

Each of the two adjacent high-pressure cylinders 3 with reagents for obtaining a gas-powder medium is connected through a separate shut-off and start-up unit 7 with a gas-powder medium exit pipe 6 common for both cylinders brought out of the body through a flat transverse and perforated partition. The branch pipe 6 is mounted on the output rigid tube 8, which is held in the housing on the bracket 9, which is a support for fixing the branch pipe of the gas-powder medium outlet in the upper part of the housing near the perforated and transverse partitions.

On supports 2 cylinders 3 are inclined towards the bottom wall of the housing at the specified partitions (perforated and flat transverse) at an angle to the longitudinal axis of the housing. Velcro straps are also provided on these supports for attaching cylinders to the support cradles 2

All components of the powder fire extinguishing module inside the housing are rigidly interconnected by means of rigid intermediate elements. For example, the shut-off device 7, which is screwed or inserted into the balloon 3 with one end 10, is positioned by the balloon 3 as its continuation. But structurally, the shut-off and starting device 7 consists of a body, inside of which there is a hollow sleeve 11, which is pressed by a spring away from the membrane 12, which seals the cavity of the cylinder from the external environment. A transverse channel is made in the body, in which a pyrotechnic element 13 is located, and the outlet part of this channel communicates with the control cavity of the hollow sleeve 11. The pyrotechnic element 13 is made with contact wires, which are passed through a tubular guide 14 screwed into the body of the locking-starting device and connected to contact groups in the communication block 15, sitting on this guide 14. The wires of the pyrotechnic elements, enclosed in rigid tubular guides, are connected to the communication block 15 used for communication with the power supply, fixed on these tubular guides, like on supports.

The input contact group of the communication block is designed to be connected either to a temperature sensor or a gas analyzing sensor, which can function as initiators of issuing a control signal to a pyrotechnic element to detonate it, or to a wired communication system with a remotely located button, pressing which provides a control signal to the pyrotechnic element to detonate it. . When a signal is received, the pyrotechnic element explodes, the gas pressure from which enters the control cavity of the hollow sleeve 11 and, overcoming the force of the spring preload, displaces the sleeve towards the membrane and breaks it, ensuring the passage of the flow of the reacted components of the cylinder through the cavity of the sleeve to the outlet of the housing, to which is connected to the output rigid tube 8 for supplying the gas cloud to the branch pipe. Taking into account this layout of the module, it becomes clear the need to preserve the mechanical links and exclude the action of dynamic loads on them.

The points 16 of attaching the suspension 4 to the body 1 are displaced along the length of the body towards the blind end to position the body in a suspended state at an angle to the floor of the room (by providing a shift in the center of gravity). This allows you to direct the nozzle 6 towards the floor or the central zone of the room.

This utility model is industrially applicable and can be repeated many times. The model allows you to hide a purely functional device - a powder module for fire extinguishing - in a shell that externally imitates a searchlight and does not allow you to determine the real purpose of the product. This casing is designed for use on modules with a total capacity of 10 liters, two high-pressure red cylinders, which are in the "joint storage" version. The casing is made of corrosion-resistant materials, it is a box closed on all sides with a suspension to ensure installation on the ceiling or beam of a building (structure).

The claimed utility model is an original example of the modern phenomenon of "incorporeal design", when its function is not manifested in the form of an object. That is, the component that links the shape of the object with the purpose of the object is lost. In reality, this corresponds to a situation where the consumer likes the external form, but he does not understand from this form what kind of product and what it is intended for. The “incorporeal design” phenomenon is used exclusively for cases when it is necessary to “hide” a product from the eyes (due, for example, to the fact that it does not fit into the interior, but should be according to the norms). The discrepancy between the shape of the device case and its functionality made it possible to hide the purpose of the device and thereby divided the form and purpose into independent components due to the loss of signs indicating the purpose of the module. At the same time, the outer shape of the casing for hiding the powder module is made in an interesting shape, imitating a projector lamp, to which no one usually pays attention and which does not cause feelings of possible danger or alertness. At the same time, for specialists, such a body imitating a searchlight generates signal information in the form of a color spot that stands out in relation to the usual colors of searchlights.

Despite the possibility of solving the problem of masking the functional component of the object, the problem of increasing the strength properties of the device is also being solved by giving the case an octagonal prism shape in the longitudinal and inclined arrangement of its side walls. Inside the suspended case there is a rather weighty module, the load from which falls on the bottom wall of the case. But with an octagonal shape, each adjacent wall that is located. at an angle to the neighboring one, performs the function of a stiffener, in which the deformation vector changes its direction.

This makes it possible to evenly distribute the weight load of the lower wall to the adjacent upper walls located to the side. Strengthening the strength properties of the body are the wall of the blind end and a flat partition on the other end. This made it possible to organize a system of supports for the module components on the walls of the case inside it, the position of which at the points of connection with the case does not change positionally. Such a power structure of the body provides the possibility of placing two cylinders in order to scale the size of the gas-extinguishing cloud, and to use the device in large areas. With an inclined arrangement of high-pressure cylinders (in fact, about the diagonals of the prism of the body), the longitudinal dimensions of the device are reduced, and the proportionality of the length and height of the body appears, which begin to correspond to the overall proportions of a traditional projector lamp.

Claims (1)

A gas-powder fire extinguishing device for a closed room, characterized in that it contains a gas-powder fire extinguishing module located in a housing on which a suspension is fixed for attaching to the elements of the ceiling part of the room, the housing is made of thin-sheet corrosion-resistant material of an octagonal shape in cross section in the form of an octagonal prism with side faces located along the length of the body, one end of which is blind, and the other end is closed by a perforated partition, behind which a transverse flat partition is placed in the body, the points of attachment of the suspension to the body are shifted along the length of the body towards the blind end to position the body in a suspended state obliquely to the floor of the room, the gas-powder fire extinguishing module includes two adjacent high-pressure cylinders with reagents for obtaining a gas-powder medium, each of which is connected through a separate shut-off and starting unit with a common outlet for both cylinders out of the body through a flat transverse and perforated partitions with a branch pipe for the outlet of the gas-powder medium, while supports are mounted in the body for fixing the cylinders obliquely towards the bottom wall of the body at the indicated partitions at an angle to the longitudinal axis of the body and a support for fixing the branch pipe for the outlet of the gas-powder medium in the upper part of the body at these partitions, each shut-off and starting unit is made with a movable element used to pierce the membrane that isolates the cavity of the cylinder from the external environment, and with a pyrotechnic element for generating gas pressure to shift the movable element towards the membrane, and the wires of the pyrotechnic elements are enclosed in rigid tubular guides and connected to the communication unit used for communication with the power supply, fixed on these tubular guides.

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