RU122298U1 - COMBINED FIRE EXTINGUISHING MODULE - Google Patents

Abstract

1. Combined fire extinguishing module, including a cylindrical thin-walled flexible tube closed at the ends, filled with a fire extinguishing agent in a liquid or gaseous state under an excess pressure relative to the environment, a piercer rigidly fixed to the tube wall, made in the form of a chamber with a pyro igniter, a nozzle, fire extinguishing agent sprays and a powder charge, and the extinguishing agent sprays are made on the surface of the punch interacting with the tube, in the form of ducts communicating with the nozzle, one of which is circular and the other is rectilinear, characterized in that it is equipped with brackets for attaching the punch to the tube walls , and on the outer surface of the punch chamber, there are cradles for attaching the punch to the tube walls, while each bracket is mounted with a corresponding cradle with a gap and with the possibility of covering and pressing the tube section, grooves are made on the surface of each cradle, the punch is It is tightly fixed by means of cradles and staples on distant sections of the tube, the nozzle is made in each cradle. 2. The module according to claim 1, characterized in that the powder charge is made of an aerosol-forming composition. The module according to claim 2, characterized in that the powder charge is made in the form of a monolithic cylindrical checker with a central axial channel. The module according to claim 3, characterized in that the punch chamber is mounted in such a way that its longitudinal axis is parallel to the longitudinal axis of the tube sections on which the punch is fixed. The module according to claim 4, characterized in that the punch is fixed on sections of the tube,

Description

The utility model relates to fire fighting equipment, and more particularly to automated volumetric extinguishing devices of combined action, including a fire extinguishing agent that is constantly under pressure and an aerosol-forming composition, and can be used for volumetric or local-volumetric fire extinguishing in closed or semi-enclosed rooms, including technically complex objects with a dense arrangement of equipment, mainly vehicle compartments, electrical panels, technological installations, kt saturated with electronics.

A gas fire extinguishing device is known from the prior art, comprising a tube with hermetically sealed ends filled with a fire extinguishing agent, a pressure indicator in the tube and a stopper with a power bandage, the stopper being mounted at the end of the tube so that the power bandage covers the tube and the mating part is inserted with an interference fit inside the tube, in addition, the stopper is equipped with a checker of flammable aerosol-forming extinguishing agent installed in the through axial channel of the stopper with the possibility of interaction bursting disc. See, US Pat. RU, cl. А62С 35/00, No. 2407572, published December 27, 2010. A disadvantage of the known device is the locality and direction of its forced start (opening the tube), carried out only from one of the ends, which significantly limits the response time and especially the fire extinguishing efficiency due to the uneven filling of the protected volume with a fire extinguishing substance.

Known fire extinguishing module, including a closed at the ends of a cylindrical tube filled with a fire extinguishing agent in a liquid or gaseous state under pressure excessive in relation to the environment, and an opening mechanism made in the form of a hollow body and a clamp attached to one of its ends with with a gap and with the possibility of preloading, on adjacent surfaces of the housing and the clamp, semi-cylindrical grooves are made facing one another, covering the tube, on the surfaces of the grooves in the middle part orpusa and clamp an annular groove, the housing is mounted perpendicular to the longitudinal axis of the tube, wherein the solid fuel is placed within the housing block of pyrotechnic aerosol composition, and on the surface of the collar opposite the channel in the bottom of the housing coaxially with a through hole. See, US Pat. RU, cl. А62С 35/00, No. 2383373, published 03/10/2010. A disadvantage of the known fire extinguishing module is the point-like nature of the forced opening of the tube with the extinguishing agent concentrated in one place, usually in its central part, which reduces the speed of the module especially with a significant length and small diameter of the tube due to the increase in the duration of the expiration of the extinguishing agent.

A known fire extinguishing system, including a container with a fire extinguishing agent made in the form of a cylindrical thin-walled flexible tube, a piercer rigidly fixed to the tube wall with a powder charge and pyrozapal and made in the form of a chamber with a nozzle directed to the tube wall, the pyrozal is mounted on the opposite end of the chamber, the powder the charge is installed inside the chamber and is made in the form of a monolithic checker with a profiled surface, spray guns are made in the form of grooves on the surface of the breakdown an egg interacting with the tube, while the grooves are in communication with the nozzle, one of them is made circular, and at least one is rectilinear, mainly the camera is mounted so that its longitudinal axis is parallel to the longitudinal axis of the tube, which is made of polyamide, and the checker powder charge is made with a Central axial channel, see, US Pat. RU, cl. А62С 35/02, No. 2407573, published December 27, 2010. This well-known design decision was made as a prototype, as the closest analogue in technical essence and achieved result. The fire extinguishing system according to the prototype is characterized by increased speed and reliability of opening the container with a fire extinguishing agent without explosive effects.

The disadvantage of the prototype is the increased time and incompleteness of the flow of extinguishing agent from a cylindrical thin-walled flexible tube with the operation of a punch mounted on its wall with a powder charge. The opening of the tube by means of the punch is local in nature and is carried out in one single place, while the value of the flow cross section, which determines the expiration time, cannot exceed the doubled value of the cross-sectional area of the tube, which is not always sufficient for a quick and complete outflow of extinguishing agent. In addition, the localization of the opening section of the tube probably increases the distance to a possible source of ignition. An increase in the number of devices installed in one protected volume, or an increase in the number of opening mechanisms mounted on one tube of increased length, does not allow for simultaneous opening. These disadvantages of the prototype significantly reduce the effectiveness of the fire extinguishing system, limit the scope of its application in protected objects of more than two cubic meters, especially if there are depressurization places, open shutters, vents, transoms, etc. in their enclosure.

The utility model is aimed at achieving a technical result, which is expressed in accelerating and increasing the completeness of the flow of extinguishing agent from the tube when the punch is triggered by simultaneously opening the tube in several places spaced apart from each other along the length of the tube. Ultimately, the specified technical result improves the efficiency of the combined fire extinguishing module. In the utility model, all the positive properties of the prototype are maximally preserved, the most important of which are the reliability and speed of opening the container with the extinguishing agent, and the absence of explosive effects.

The specified technical result is achieved by the fact that the module of combined fire extinguishing, including a cylindrical thin-walled flexible tube closed at its ends, filled with a fire extinguishing agent, in a liquid or gaseous state under pressure that is excessive in relation to the environment, a piercer rigidly fixed to the tube wall, made in the form of a chamber with pyrozapal, nozzle, spray guns and powder charge, and spray guns are made on interacting with t the surface of the punch, in the form of grooves communicating with the nozzle, one of which is circular and the other straight, differs from the prototype in that it is equipped with brackets for attaching the punch to the walls of the tube, and on the outer surface of the punch chamber there are lodges for attaching the punch to the walls of the tube, with each bracket mounted with an appropriate lodgement with a gap and with the possibility of coverage and preload of the tube, grooves are made on the surface of each lodgement, the punch is rigidly fixed to by means of lodgements and brackets on spaced sections of the tube, the nozzle is made in each of the lodgements.

The optimal from the point of view of achieving the specified technical result is the implementation of the powder charge from the aerosol forming composition in the form of a monolithic cylindrical checker with a central axial channel. It is preferable that the punch chamber be arranged in such a way that its longitudinal axis is parallel to the longitudinal axis of the tube sections on which the punch is fixed, one quarter of its length from the ends of the tube. Alternatively, the ends of the tube may be turned in opposite directions or in the same direction. In all versions of the described module, it is advisable to make a through hole in the brackets, opposite the nozzle and aligned with it. The best structural material for the manufacture of the tube is polyamide.

The main fire extinguishing element of the combined fire extinguishing module is a cylindrical tube filled with a liquid or gaseous substance, for example freon 125, under excess pressure with respect to the environment. The opening mechanism of the tube is also an additional fire extinguishing element, since a multicomponent fire extinguishing gas is formed from the aerosol-forming composition during the combustion of a charge. The aerosol-forming composition, for example, APIS, manufactured according to TU4854-001-96497910-2005, includes finely divided solid components in its formulation, the components most often used in the powder industry, such as soot, aluminum powder such as ASD, iron oxide and others, are used particle sizes from 1 to 20 microns.

The operation of the combined fire extinguishing module is based on the principle of opening a cylindrical thin-walled flexible tube filled with a fire extinguishing substance that is in a liquid or gaseous state under pressure that is excessive in relation to the environment and simultaneously in two places one quarter of its total length from the ends of the tube. Thus, a halving of the time of complete expiration of the extinguishing agent from the tube and a decrease in the spread in time of the expiration of the extinguishing agent are achieved. The autopsy is carried out by means of one punch so that the outflow of the extinguishing agent from the tube occurs from four equal volumes and ends simultaneously. The punch in the form of a chamber with nozzles can be reliably fixed to various sections of the tube at any place along its entire length by means of brackets parallel to the longitudinal axis of the tube, which significantly increases the convenience of the module layout. The spray device of the extinguishing agent in the form of a system of rectilinear and annular grooves communicating with the nozzle cavity provides a directed flow of gases along the tube wall during combustion of a solid fuel pyrotechnic checker and its uniform opening. A powder charge of an aerosol forming composition made in the form of a monolithic cylindrical block with a central axial channel is an effective means of gas generation. Such a checker is technologically advanced in production, simple in layout, oxygen is not required for its combustion, and powder gases have high energy and high temperature, which guarantees the creation of optimal conditions for reliable opening of the tube wall regardless of the initial temperature. The constructive combination of two opening points of the tube in one node can significantly simplify the design, increase its speed. The manufacture of a tube made of polyamide, which has increased strength and good flexibility in a wide temperature range, provides convenient installation and reliable interaction of the tube with the punch.

The structural diagram of the fire extinguishing module according to the utility model maximizes its autonomy and reliability in the conditions of many years of maintenance-free use. The combined fire extinguishing module is recommended for use in any climatic zones, its reliability and durability is confirmed by tests.

Thus, all the features of the combined fire extinguishing module that are distinctive from the prototype are aimed at obtaining and are sufficient to achieve a technical result, namely, acceleration and increase in the completeness of the extinguishing agent from the tube when the punch is triggered, increasing the efficiency of the module.

The combined fire extinguishing module, characterized by the described set of essential features, is new and industrially applicable.

The technical solution is illustrated by drawings.

Figure 1 shows a General view of the module of combined fire extinguishing in which the ends of the tube are turned in opposite directions; figure 2 - the ends of the tube are turned in one direction; figure 3 - punch in section with parallel sections of the tube; figure 4 is a transverse section of the punch AA in figure 3.

The combined fire extinguishing module consists of a cylindrical thin-walled flexible tube 1 made of polyamide, the ends of which are closed, for example, are sealed and extinguishing agent 2 is placed inside in a liquid or gaseous state under pressure that is excessive in relation to the environment. As extinguishing agent 2 can be used freon 125 under pressure of saturated vapor. The tube 1 as a part of the module forms a loop closed by a punch 3 rigidly fixed on its wall. The length of the loop is approximately two quarters of the total length of the tube 1, thus, the punch 3 is fixed on two parts of the tube 1 one quarter of its length from the ends. In figures 1 and 2, the maximum distance from the ends of the tube 1 to the punch 3 is indicated by the letter L. Two different versions of the installation of the punch 3 on the tube 1 are possible, when the ends of the tube 1 are turned in opposite directions (figure 1) and in one direction (figure 2). From the point of view of the speed and completeness of the flow of the extinguishing agent 2 from the tube 1, when the punch 3 fixed on its wall is triggered, both versions are equivalent when observing the length of the loop and are determined by the layout conditions on the protected object. The punch 3 consists of a chamber 4 in which an aerosol-forming powder charge is located, made in the form of a monolithic cylindrical checker 5 with a central axial channel. The chamber 4 is equipped with a threaded cover 6, in which a pyrozap is installed 7. On the outer surface of the chamber 4 along its generatrix two lodges 8 are made, intended for fastening the punch 3 to the walls of the tube 1. The lodges 8 are cylindrical gutters made on both sides of the chamber 3 into which the tube section 1 fits snugly. Each lodgement 8 corresponds to an overhead clip 9 also having a surface in the form of a cylindrical groove. The bracket 9 together with the lodgement 8 cover the portion of the tube 1 and provide fastening of the punch to the walls of the tube 1. The bracket 9 is attached to the lodgement 8, with the formation of a guaranteed gap 10, with studs 11, which provide the necessary density and force to compress the portion of the tube 1 to the groove. Advantageously, the chamber 4 of the punch 3 is oriented in such a way that its longitudinal axis is parallel to the longitudinal axis of the sections of the tube 1 on which the punch 4 is fixed, moreover, they are located in the same plane as shown in figure 3, which ensures the maximum spray area of the extinguishing agent 2 Nozzles 12 are made in the form of through holes in each of the lodges 8 and simultaneously in the wall of the chamber 4 from the bottom, are perpendicular to the longitudinal axis of the tube 1. On the surface of the punch 4, I interact a conductive tube 1, i.e. on the surface of the gutter are located spray guns 2, which are made in the form of communicating with the nozzle 12 of the annular 13 and rectilinear 14 channels. The annular groove 13 is located in the plane of the cross section of the tube 1 and has the shape of an arc, and the straight groove 14 is located along the generatrix of the tube 1 along the entire length of the lodgement 8. In the bracket 9 there is a through hole 15 located opposite the nozzle 12, coaxial with it, but with a larger diameter .

The combined fire extinguishing module operates as follows.

The module is permanently mounted on the site to be protected with the maximum approximation of the punch to the place of the most likely occurrence of fire. The module is launched forcibly or spontaneously when the primary signs of fire appear. Forced start can be carried out manually by the operator, or in automatic mode by command from the starting device. During a forced start, an electric impulse with a current strength of 0.1 to 1A is supplied to the terminals of the pyrozapal 7. Pyrozapal 7 initiates a force of flame, which sets fire to the checker 5 of the aerosol-forming powder charge. The combustion products of the checkers 5 through the gas-connected nozzles 12 simultaneously affect the surface of both sections of the tube 1. By their thermal and erosive effects, the combustion products of the checkers 5 break through the wall of the tube 1 and, together with the extinguishing agent 2 exiting from it, along the annular 13 and rectilinear 14 grooves and through the gap 10 enter the fire zone. Upon receipt of the extinguishing agent 2 in the fire, the effect of local and volume fire. The erosive effect of the products of combustion of the checker 5 on the material of the tube 1 is also carried out in the grooves 13 and 14, increasing the area of opening of the tube. If there are 9 through holes in the brackets 9, the combustion products of the checkers 5 during the operation of the module by their thermal and erosive effects break through the tube wall 1 also against the holes 15 i.e. through and even more increase the area of expiration. When using an aerosol forming extinguishing composition as a formulation, an additional fire extinguishing effect is created due to the inhibitory effect of the aerosol on redox reactions in the gas-flame combustion zone. In this case, the aerosol is additionally cooled by the extinguishing agent 2 flowing out of the tube, and this substance flows out more intensively due to the heating effect of the aerosol, which in turn also enhances the joint fire extinguishing effect of the two-phase gas-aerosol mixture. In the process of extinguishing, equipment is also cooled. Fire extinguisher 2 (Freon 125) is safe and non-conductive, does not have harmful corrosive and chemical effects on metals, plastics and electrical equipment, and does not pose a danger to people. After the fire is extinguished, the freon evaporates. When triggered, the tube 1 does not have any mechanical effect on the equipment and wiring.

The advantage of the combined fire extinguishing module according to the utility model is its simplicity, reliability and efficiency. The operation of such a module is not economically and technically fraught with significant costs.

The examples of the implementation of the combined fire extinguishing module described above are not exhaustive and are given only for the purpose of explaining the utility model and confirming its industrial applicability. Specialists in this field can improve it and / or implement alternative options within the essence of this utility model, as reflected in the description and drawings.

Claims (9)

1. The module of combined fire extinguishing, including a cylindrical thin-walled flexible tube closed at its ends, filled with a fire extinguisher in a liquid or gaseous state under excessive pressure in relation to the environment, a piercer rigidly fixed to the tube wall, made in the form of a chamber with a pyrozapal, a nozzle, fire extinguishing agent sprayers and a powder charge, moreover, fire extinguisher spraying devices are made on the surface of the punch interacting with the tube, in the form of communicating groove nozzle, one of which is circular and the other straight, characterized in that it is equipped with brackets for attaching the punch to the tube walls, and on the outer surface of the punch chamber, lodges are made for attaching the punch to the tube walls, each bracket being mounted with a corresponding lodgement with a gap and with the possibility of covering and preloading the tube section, grooves are made on the surface of each lodgement, the punch is rigidly fixed by means of lodgements and brackets on the spaced apart section x tube, the nozzle is made in each of the lodges. 2. The module according to claim 1, characterized in that the powder charge is made of an aerosol forming composition. 3. The module according to claim 2, characterized in that the powder charge is made in the form of a monolithic cylindrical checker with a central axial channel. 4. The module according to claim 3, characterized in that the punch chamber is mounted in such a way that its longitudinal axis is parallel to the longitudinal axis of the tube sections on which the punch is fixed. 5. The module according to claim 4, characterized in that the punch is fixed to sections of the tube one quarter of its length from the ends. 6. The module according to claim 5, characterized in that the tube is made of polyamide. 7. The module according to claim 6, characterized in that the ends of the tube are turned in opposite directions. 8. The module according to claim 6, characterized in that the ends of the tube are turned in one direction. 9. The module according to claim 7 or 8, characterized in that a through hole is made in the bracket opposite the nozzle and aligned with it.