RU2383373C1 - Fire-extinguishing module - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: fire-extinguishing module comprises cylindrical tube closed at ends and filled with fire-extinguishing substance in liquid or gaseous condition under pressure, which is excessive versus environment. Mechanism of tube opening is arranged in the form of hollow body and yoke attached to one of its ends with clearance and with the possibility of pressing, on adjacent surfaces of body and yoke there are semi-cylindrical bores arranged as inverted towards each other and enclosing tube, and circular groove is arranged on surfaces of bores in middle part of body and yoke. Body is installed perpendicularly to longitudinal axis of tube, on free end of body there is cover fixed with central hole, in which initiation unit is mounted. On body bottom inverted to tube there is channel arranged, which communicates to circular groove, besides inside body there is solid fuel pyrotechnical blasting cartridge placed as made of aerosol-forming composition, including finely dispersed solid components, for instance soot, aluminium, ferric oxide. At least one blasting heat-sensitive cord is fixed on external side surface of tube.

EFFECT: improved performance and efficiency of module.

12 cl, 4 dwg

Description

The invention relates to fire fighting equipment, and more specifically to automated volumetric extinguishing devices of combined action, including an extinguishing agent that is constantly under pressure, and an aerosol-forming composition, and can be used for volumetric or locally-volumetric fire extinguishing in closed or semi-enclosed rooms, including the number of technically complex facilities with a tight layout of equipment, mainly vehicle compartments, electrical panels, technological installations, facility s saturated with electronics.

A prior art device for extinguishing a fire in a semi-enclosed volume, characterized in that the powder charge is placed in a flexible combustible tube, inside which a flame-retardant cord or an electrically heated wire is introduced along the entire length, see Pat. RU, cl. А62С 13/22, No. 2111030, published 1998.05.20. The invention provides a time for supplying a fire extinguishing aerosol not exceeding 2-3 s. A disadvantage of the known device is the need to turn on an ignition device to initiate a TTK charge placed in the tube and in a metal perforated casing.

Known linear fire extinguisher to protect the engine compartment of a vehicle, comprising a flexible plastic tube filled with a fire extinguishing composition with multiple local wall weakenings, see US Pat. US cl. A62C 35/00, No. 6161624, published 2000.12.19. A disadvantage of the known fire extinguisher is the complexity of its design, associated with the multilayer structure of the tube, which affects its economic characteristics.

Known fire extinguishing tube for protecting the engine compartment "Proteng", manufactured according to the technical specifications ATS 580053/314 by the company "ATServis, as", Slovak Republic, Krajinska cesta 32,921 01 Piestany, t. (1042133) 7729984, which is a sealed cylindrical polyamide sealed a 2.5 m long tube, 12-18 mm in diameter, filled with FE-36 or 227 freon under pressure that is excessive in relation to the environment. The self-triggering mechanism is embedded in the very nature of the material of the tube made of polyamide, with a local increase in temperature on the wall above 220 ° C, it softens and collapses with the formation of a nozzle with a diameter of up to 20 mm, through which the extinguishing agent flows into the protected compartment. The PROTENG gas fire extinguishing system, used to protect the engine compartment of a car, combines simplicity, reliability and complete autonomy. This well-known design decision was made as a prototype as the closest analogue in technical essence and achieved result.

The disadvantage of the prototype is the need for significant local heating of the extinguishing tube to high temperatures for the formation of the nozzle. This heating process takes from several seconds to several tens of seconds and characterizes the high inertia of the installation. A paradoxical situation may arise when a person, in this case the driver, sees a fire in the engine compartment of the car, but can do almost nothing, since the installation does not imply a forced start. Meanwhile, in a matter of seconds, a fire can destroy a significant part of the equipment and cause irreparable damage. In addition, the fire extinguishing tube requires careful tracing when laying with the maximum approximation to the places of the likely occurrence of the fire. These disadvantages of the prototype significantly reduce efficiency and limit its scope.

The present invention is aimed at achieving a technical result, which is expressed in providing the ability to install the opening mechanism of the tube anywhere along its length, providing a forced manual or automatic start when the first signs of fire occur. Ultimately, the specified technical result allows to increase the efficiency and speed of the fire extinguishing module. In the fire extinguishing module, all the positive properties of the prototype are maximally preserved, the most important of which are the constant readiness of the installation and the possibility of its self-starting at any relative position of the tube and the likely source of ignition.

A positive result is achieved by the fact that the fire extinguishing module, which includes a cylindrical tube closed at the ends, filled with a fire extinguisher in a liquid or gaseous state under excessive pressure in relation to the environment, and the opening mechanism of the tube differs from the prototype in that it has an opening mechanism made in the form of a hollow body and a clamp attached to one of its ends with a gap and with the possibility of preload. Moreover, on adjacent surfaces of the housing and the clamp, semi-cylindrical grooves are made facing one another, covering the tube, and an annular groove is made on the surfaces of the grooves in the middle of the housing and the clamp. The housing is mounted perpendicular to the longitudinal axis of the tube. A cover with a central hole is fixed on the free end of the housing. A channel communicating with an annular groove is made at the bottom of the housing facing the tube, and a solid fuel pyrotechnic checker is placed inside the housing, and an initiation unit is mounted in the opening of the housing cover.

In all versions of the described module, the solid fuel pyrotechnic checker can be made of an aerosol-forming composition, the formulation of which contains finely divided solid components, for example, carbon black, aluminum, and iron oxide.

At least one flame-retardant heat-sensitive cord can be fixed on the outer side surface of the module tube at the main point, the end section of which is passed through the gap between the tamper box and the clamp, through the annular groove on the groove of the housing and through the channel in the bottom of the housing, inserted into the housing with the possibility of contact with a solid fuel pyrotechnic checker.

A through hole is made coaxially with a through hole coaxially with a hole in the module with a bomb of aerosol-forming composition on the surface of the clamp opposite the channel in the bottom of the housing; a hollow spacer with a supporting platform for the checker is installed between its bottom and the checker, and the height of the spacer is 0.5-1 the height of the checker . Alternatively, an annular support for the checker can be made on the inner surface of the casing, the distance from the support to the end of the casing being 0.5-1 of the height of the checker.

Optimal from the point of view of achieving the indicated technical result is the implementation of a cylindrical-shaped checker with a central axial channel, inside of which, on the one hand, an initiation unit enters, and on the other, an end portion of a heat-conducting heat-sensitive cord. The channel in the bottom of the housing can be blocked by a sealing membrane, and the flame-retardant heat-sensitive cord is fixed along the generatrix of the tube along its entire length and is closed by a thin-walled protective sheath.

It is preferable to equip the module with a signal-starting device, and the initiation unit with an electric stop, the terminals of which are connected to the output terminals of this device. At the same time, the terminals of the electric valve can additionally be connected to the manual start toggle switch connected to the power source.

The main fire extinguishing element of the module is a cylindrical tube filled with a liquid or gaseous substance, such as FE-36 or 227 freon, under pressure that is excessive in relation to the environment. The walls of the tube are made of polyamide, which is a dielectric resistant to chemical influences and has increased strength. This design of the tube eliminates false triggering of the module when shaking during installation. The opening mechanism of the tube is also an additional fire extinguishing element. The hollow body by means of a clamp can be reliably fixed to the tube anywhere along its entire length. Semicylindrical grooves covering the tube on adjacent surfaces of the housing and the clamp, in combination with annular grooves and a channel and a through hole communicating with them, provide directed gas flow along the tube wall during combustion of a solid fuel pyrotechnic checker. The solid propellant pyrotechnic checker is in this case the most effective tool, since it is autonomous, oxygen is not required for its combustion, and powder gases have high energy and high temperature, which guarantees the creation of optimal conditions for the formation of a nozzle in the tube wall, regardless of the initial temperature. The electric fuse of the initiation unit, mounted in the opening of the housing cover, has instantaneous action and perfect compatibility with a solid state checker. The constructive combination of these elements in one housing allows you to significantly simplify the design, increase its reliability and durability. The presence of a tube opening mechanism solves several problems simultaneously. There is no need for careful tracing of the tube, eliminating the possibility of delayed operation or failure of the module. The presence of a flame-resistant heat-sensitive cord significantly increases the reliability and speed of the module, since it is more sensitive to temperature increase and less inertial. This design scheme of the fire extinguishing module maximizes its autonomy and reliability in conditions of many years of maintenance-free use.

The module components can be transported by any means of transport without limiting the range and height, stored in any storage conditions. The system is recommended for use in all climatic zones. Reliability and durability of the fire extinguishing system is confirmed by tests simulating operational loads and accelerated climatic tests.

Thus, all the fire-extinguishing module features that are distinct from the prototype are aimed at obtaining a technical result, namely, providing the possibility of installing the opening mechanism of the tube anywhere along its length, forcing manual or automatic start when the first signs of fire and self-starting occur at any relative position of the tube and the probable the source of ignition and thereby increasing efficiency and speed.

The fire extinguishing module, characterized by the described set of essential features, is new, industrially applicable and has an inventive step.

The technical solution is illustrated by drawings.

Figure 1 shows a General view of the fire extinguishing module; figure 2 is a cross section of the fire extinguishing module aa in figure 1; figure 3 - node B in figure 2 mounting the pieces of the aerosol forming composition on a hollow spacer with an increase; figure 4 - circuit diagram of the forced start of the fire extinguishing module.

The fire extinguishing module consists of a hollow cylindrical tube 1, the ends of which are closed, for example, with plugs or sealed, and a fire extinguishing substance 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 under pressure of saturated vapor. On the outer surface of the tube 1, a hollow body 3 is installed perpendicular to its axis, to which the clamp 5 is attached. The clamp 5 and the housing 3 are pressed against the tube 1 so that a gap is formed between the clamp 5 and the end of the housing 3 facing the tube 1 6. On the surfaces of the housing 3 and the clamp 5 in contact with the tube 1, cylindrical grooves 7 and 8 are made facing one another, on which, in turn, an annular groove 9 and 10 is made. Grooves 9 and 10 are made in a half ring on each groove 7 and 8. On the upper end of the housing 3 is fixed cover 11 a central opening in which is mounted initiate opening mechanism unit 12, such as a standard igniter triggered upon application of a pulse of electric current.

In the cavity of the housing 3 there is a checker 13 made of a solid fuel pyrotechnic composition, for example, an aerosol-forming composition, during the combustion of which a fire-extinguishing aerosol is formed. Finely dispersed solid components are introduced into the pyrotechnic composition, the components used in the powder industry, such as carbon black, aluminum powder such as ASD, iron oxide and others with particle sizes from 1 to 20 microns, are most often used. Between the bottom of the housing 3, facing the tube 1, and the end face of the checker 13, a damping cavity 14 is formed, the height of which is from 0.5 to 1.0 the height of the checker 13 depending on the desired operating mode of the device. For the formation of a cavity, either a hollow spacer 15 with a supporting platform for the checker 13 or an annular support 16 made on the inner surface of the housing 3 is used. The use of a hollow spacer 15 makes it possible to vary the dimensions of the checker 13 depending on the required fire extinguishing efficiency of the module. In the bottom of the housing 3 adjacent to the tube 1, a channel 17 is made, communicating with the annular grooves 9 and 10 on the cylindrical grooves 7 and 8. In the clamp 5, opposite the channel 17 of the housing, a through hole 18 is made coaxially with this channel 17. On the outer side the surface of the tube 1 to increase the sensitivity of the module to an external heat pulse that occurs during a fire, a heat-sensitive flame-retardant cord 19 made of a plastic powder composition can be routed. One end of the cord 19 is laid through the gap 6 between the housing 3 and the clamp 5, then through the annular groove 9 on the groove 7 of the housing 3 and through the channel 17, the cord 19 is passed into the housing 1 until it touches the surface of the checker 13. For this design of the module, it is preferable to make the checker 13 a cylindrical shape with an axial channel 20. In this case, a flame-retardant heat-sensitive cord 19 enters into it from one end of the channel 20, and an initiation unit 12 from the other. The cord 19 can be fixed to the surface of the tube 1 both along its generatrix and along the winding shouted at the entire length of the tube 1. From the outside, the cord 19 is protected from the action of external aggressive media by a thin-walled shell, for example, a plastic film 10 ... 20 μm thick. The channel 17 of the housing 3 to protect the checkers 13 and the initiation unit 12 from external aggressive factors is blocked by a sealing membrane 21. The electrical circuit for the forced start of the fire extinguishing module also includes a manual start switch 22 connected to a power source 23, and an automatic signal-starting device 24, outputs which is electrically connected to the conclusions of the initiation node 12.

The fire extinguishing module operates as follows.

The module is launched forcibly or spontaneously when the primary signs of fire appear. Forced start can be carried out manually by the operator by means of the manual start toggle switch 22 connected to the power source 23, or in automatic mode by a command from a standard automatic signal-starting device 24. During a forced start, an electrical impulse of 0.1 up to 1A. The initiation unit 12 produces a force of flame, which ignites the checker 13. The combustion products of the checker 13 through the damping cavity 14, softening the initial impact of the force, pass through the channel 16, breaking the sealing membrane 20, through the annular groove 9 to the surface of the tube 1. Their thermal and erosive effect the combustion products of the checkers 13 break through the wall of the tube 1 and, together with the extinguishing agent 2 flowing from it, through the gap 6 between the end face of the housing 3 and the clamp 5 enter the fire zone and eliminate it. The erosive effect of the products of combustion of the checker 13 on the material of the tube 1 is enhanced by the presence in the formulation of the checker 13 finely divided solid particles. 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. Part of the gas-aerosol mixture through the annular groove 10 in the cylindrical groove 8 of the clamp 5 enters the through hole 18, and through it into the zone of the fire source.

Self-triggering, or self-starting, occurs in the event of an operator’s inaction, which for some reason cannot start the fire extinguishing system (in-place at the time of the fire, damage to the automation system, accident or damage to the cable network). In this case, when exposed to a fire flame, a fire-resistant cord 19 ignites. The ignition of the cord 19 occurs at a temperature of + 170 ° C anywhere along its length. The flame through the cord 19 enters through the gap 6, the annular groove 9, through the channel 17 into the housing 3 and ignites the checker 13. Further, the operation of the module occurs as described above. In the event of emergency damage to any elements of the module except tube 1, in emergency situations or when the fire-resistant cord 19 is not included in the module, in case of fire in the zone of the tube’s location and when the wall of tube 1 reaches a temperature of more than 220 ° C from exposure to an open flame from the source of ignition, the material the tube 1 softens and under the influence of excess pressure, an opening in the form of a nozzle opens through it through which the extinguishing agent 2 is supplied directly to the fire, eliminating it. There is the effect of local and volumetric fire extinguishing. In the process of extinguishing, equipment is also cooled. Extinguishing agent 2 (freon) is safe and non-conductive. Freon 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, tube 1 does not have any mechanical effect on equipment and wiring.

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

Claims (12)

1. Fire extinguishing module, including a cylindrical tube closed at the ends, filled with a fire extinguishing agent in a liquid or gaseous state under pressure that is excessive in relation to the environment, and a tube opening mechanism, characterized in that the opening mechanism is made in the form of a hollow body and a clamp, attached to one of its ends with a gap and with the possibility of preloading, on adjacent surfaces of the housing and the clamp are made facing one another semicylindrical grooves, covering the tube, on the surface A groove is made in the middle part of the housing and the clamp, an annular groove is made, the housing is installed perpendicular to the longitudinal axis of the tube, a lid with a central hole is fixed to the free end of the housing, and a channel communicating with the annular groove is made on the bottom of the housing facing the tube, and inside the housing a solid fuel pyrotechnic checker is placed, and an initiation unit is mounted in the opening of the housing cover. 2. The module according to claim 1, characterized in that the solid fuel pyrotechnic checker is made of an aerosol forming composition. 3. The module according to claim 2, characterized in that the checker formulation contains finely divided solid components, such as carbon black, aluminum, iron oxide. 4. The module according to claim 1, characterized in that at least one heat-conducting heat-sensitive cord is fixed on the outer side surface of the tube, the end portion of which is passed through the gap between the opening of the opening mechanism and the clamp, through an annular groove on the groove of the housing and through the channel in the bottom of the case, brought inside the case with the possibility of contact with a solid fuel pyrotechnic checker. 5. The module according to claims 1 to 3, characterized in that a through hole is made coaxially with it on the surface of the clamp opposite the channel in the bottom of the housing. 6. The module according to claims 1 to 3, characterized in that a hollow spacer with a supporting platform for the checker is installed inside the case between its bottom and the checker, the height of the spacer being 0.5-1 the height of the checker. 7. The module according to claims 1 to 3, characterized in that an annular support for the checker is made on the inner surface of the body, the distance from the support to the body end being 0.5-1 of the height of the checker. 8. The module according to claims 1 to 4, characterized in that the checker is made of a cylindrical shape with a central axial channel in which an initiation unit is placed on one side and an end section of a heat-conducting heat-sensitive cord is placed on the other. 9. The module according to claims 1 to 3, characterized in that the channel in the bottom of the housing is closed by a sealing membrane. 10. The module according to claim 4, characterized in that the flame-retardant heat-sensitive cord is fixed along the generatrix of the tube along its entire length and is closed by a thin-walled protective sheath. 11. The module according to claim 1, characterized in that it further comprises a signal-starting device, and the initiation unit is equipped with an electric fuse, the terminals of which are connected to the output terminals of this device. 12. The module according to claim 11, characterized in that the terminals of the electric igniter are additionally connected to a manual start toggle switch connected to a power source.

Images