RU2407572C1 - Gas supression installation - Google Patents

Abstract

FIELD: fire fighting equipment.

SUBSTANCE: invention refers to fire prevention, while being a free-standing space suppression installation applied in closed or half-closed spaces. A gas suppression installation comprises a sealed end tube filled with a fire extinguishing agent, a tube pressure indicator with a sensor, and a stopper with a power rim. The pressure indicator in the form of an indicating pressure gauge is mounted in the tube end face with its sensor interacting with the fire extinguishing agent, while the stopper - from an opposite tube end face in such a manner that a power rim envelopes the tube, and a stopper counterpart is preloaded inside the tube and represents an annular groove on a cylindrical surface of the stopper of the width exceeding that of the power rim. The stopper has an end cap and a threaded segment with the end cap being mounted on the threaded segment, and the stopper has a through axial perforation the through axial channel.

EFFECT: invention enables the in-situ effective and operating control of the installation operability under all operating conditions.

9 cl, 4 dwg

Description

The invention relates to fire fighting equipment, and more particularly to autonomous volumetric extinguishing devices, and can be used for volumetric or local-volumetric fire extinguishing in closed or semi-closed rooms, including technically complex objects with a dense arrangement of equipment, mainly vehicle compartments, electrical panels , technological installations, objects saturated with electronics.

A linear fire extinguisher is known from the prior art, comprising an elongated tubular body with a fire extinguishing agent and a power line for starting, in which the body is made in the form of a collector with spray nozzles, an aerosol fuel charge is used as a fire extinguisher, and the power line ignites it over the entire or individual length sections collector (see US Pat. RU, CL A62C 35/00, No. 2101058, published January 10, 1998). The invention provides increased fire extinguishing efficiency due to the uniformity of the concentration of extinguishing agent. A disadvantage of the known device is the presence in it of a single means for starting, which increases the inertia of operation and reduces reliability.

Known automatic fire extinguishing system of an armored vehicle, including temperature sensors and spray guns, located in fire hazard areas of a motor-transmission unit, a control device connected to the spray gun by a pipe with a fire-extinguishing agent, a membrane, its punch and pyro cartridge, an alarm device, the input of which is connected to the cavity extinguishing agent pipelines, igniters located in fire hazardous areas of a motor-transmission installation, n an additional membrane punch and a powder charge connected by means of a flame-retardant cord with igniters (see US Pat. RU, CL F41H 7/02, No. 2098741, published on December 10, 1997). The fire extinguishing system is characterized by increased reliability. The disadvantage of the system is the presence of a container with a fire extinguishing substance in the form of a cylinder, which, due to its large size, cannot be placed directly in the fire zone, for example, in the engine compartment, heater compartment or trunk of a modern car, and even more so, military equipment compartments.

A linear fire extinguisher is known for protecting the engine compartment of a vehicle, including a flexible plastic tube filled with a fire extinguisher with multiple local weakenings of the wall and hermetically sealed ends (see US Pat. Cl. A62C 35/00, No. 6161624, published 2000.12.19). A fire extinguisher is characterized by the convenience and simplicity of layout on the protected object. This well-known technical solution was adopted as a prototype as the closest analogue in technical essence and achieved result.

The disadvantage of the prototype is the lack of means of monitoring the performance of a fire extinguisher in the process of its operation. Under conditions of increased temperature and dynamic loads, tube depressurization and leakage of extinguishing agent are possible. In the design of the prototype, monitoring the health of the device is difficult and not always possible, since it involves the dismantling of the fire extinguisher from the object, its weighing with sufficiently high accuracy, which is impossible, for example, in the field. In addition, there is no forced start mechanism in the fire extinguisher, which increases the start time of the supply of the extinguishing agent to the fire zone. These disadvantages of the prototype significantly reduce its reliability during operation and use.

The present invention is aimed at achieving a technical result, which is expressed in providing the possibility of effective and operational monitoring of the health of the device without dismantling it in any operating conditions. In addition, the device is characterized by a variety of ways to start it. Ultimately, the specified technical result improves the reliability of the fire extinguishing device. In the gas fire extinguishing device, all the positive properties of the prototype are maximally preserved, the most important of which is the simplicity of the arrangement of the device on the protected object.

The specified technical result is achieved in that the gas extinguishing device containing a tube with hermetically sealed ends filled with a fire extinguishing agent differs from the prototype in that it is equipped with a pressure indicator in the tube containing the sensing element and a stopper with a power bandage. The pressure indicator is mounted in the end of the tube with the possibility of interaction of its sensitive element with a fire extinguishing agent, and the tube is on the side of the opposite end of the tube in such a way that the power bandage covers the tube, while the counterpart of the tube is tightened into the tube and made in the form of an annular groove on the cylindrical surface of the cork, the width of which exceeds the width of the power bandage.

In all versions, we apply a pressure indicator in the form of a gauge arrow type.

The plug can be equipped with a plug and has a threaded section, while the plug is mounted on the threaded section, and a through axial channel is made in the plug. Moreover, the threaded section of the tube is made with an external thread and protruding beyond the end of the tube, and a check valve is installed in the through axial channel of the tube from the side of the extinguishing agent. Optimal from the point of view of achieving the specified technical result is equipping the cork with a bursting disc, performing a through axial channel in the cork with a step for installing a bursting disc on it.

It is preferable to equip the device with pyrotechnic means for blasting the membrane, performing a threaded portion of the tube with an external thread and protruding beyond the end of the tube with the installation of pyrotechnic means in the through axial channel of the tube from the side of the plug. However, alternatively, it is possible to equip the cork with a piece of flammable aerosol-forming extinguishing agent installed in a through axial channel with the possibility of interaction with a bursting disc. In this case, the checker can be equipped with a flammable fire-resistant cord connected to it.

The main fire extinguishing element of the system is a thin-walled flexible tube filled with a gaseous extinguishing agent, 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 or copper, which are resistant to chemical influences, static electricity and have increased strength. This design of the tube eliminates explosive and false operation.

The location of all service and functional structural elements of the device at the ends of the tube simplifies not only the design itself, but also significantly increases the convenience of layout on the protected object with coverage of all of its fire hazard zones.

Equipping the device with a pressure indicator in the tube containing the sensing element, interacting directly with the extinguishing agent, allows for constant visual monitoring of operability, as well as objectively assess the shelf life of the product. Since the pressure of the extinguishing agent in the tube is the defining parameter of the device, it is optimal to control it using a pressure gauge of the arrow type. Equipping the device on the side of one of the ends of the tube with a multifunctional stopper with a power bandage eliminates the sealing of the end of the tube, which is technologically problematic and structurally unreliable.

Installing the plug with an interference fit inside the tube in combination with a bandage covering the counterpart of the plug in the form of an annular groove on a cylindrical surface, provides reliable sealing. Exceeding the width of the annular groove, the width of the power bandage prevents the formation of grooves in the wall of the tube when it is crimped by the bandage. The cork is made predominantly metal, so it is convenient and technologically advanced to make a through axial channel, including a stepped one, to mount various elements, for example, a plug, by means of a threaded connection.

The presence of a non-return valve and a plug can significantly simplify the operation of filling the tube with a fire extinguishing agent to ensure a given pressure level. The possibility of “refueling” the tube without removing the device from the protected object makes the device indispensable in the field and practically eternal.

The presence of additional special means of starting the device, such as a bursting disc, in combination with a pyrotechnic means or a block of flammable aerosol-forming extinguishing composition with a flammable flame-retardant cord, can significantly improve and diversify the conditions for self-starting and force-start the device.

The pyrotechnic product has instant action and a long warranty period. The solid fuel checker 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 reliable opening of the bursting membrane, regardless of the initial temperature. The presence of the indicated means in the device greatly increases the duplication of the main functional elements and survivability.

The structural scheme of the fire extinguishing device maximizes its reliability, guarantees autonomy and speed, including in many years of use. Component devices can be transported by any means of transport without limiting the range and height, stored in any storage conditions. The device is recommended for use in any climatic zones. Reliability and durability are confirmed by tests simulating operational loads and accelerated climatic tests.

Thus, all the signs of a gas fire extinguishing device that are distinctive from the prototype are aimed at obtaining a technical result, namely, increasing its reliability.

A gas fire extinguishing device, 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 a gas fire extinguishing device with a channelless plug; figure 2 - the end of the tube with a tube with an external thread, plug and check valve, in section; figure 3 - the end of the tube with a cork with mounted pyrotechnic means in it, in section; figure 4 - the end of the tube with a cork with mounted checker in it, in section.

The gas fire extinguishing device consists of a thin-walled flexible tube 1 installed inside the protected object. The tube 1 is made of a polymeric material, such as polyamide, amenable to destruction by thermomechanical action. In some cases, a thin-walled flexible tube 1 can be made of fusible metal, such as copper or aluminum. Tube 1 is filled with extinguishing agent 2 under pressure that is excessive in relation to the environment (refrigerant under saturated vapor pressure). Freon is safe and non-conductive, does not have harmful corrosive and chemical effects on metals, plastics and electrical equipment, and is not dangerous to people. Tube 1 is of sufficient length to be laid in the most fire hazardous locations. The ends of the tube 1 are hermetic, one of them is hermetically sealed by a pressure indicator 3, for example, a pressure gauge of the type from the range commercially available by the industry, necessary to control the presence of extinguishing agent during operation of the device. The pressure indicator 3 has a sensing element 4, represented by a rod and a piston sealed along the contour. The sensing element 4 is mounted in the end of the tube 1 with the possibility of interaction directly with the extinguishing agent 2. The opposite end of the tube 1 is blocked by a plug 5 installed with interference, for example by pre-heating the tube 1. The plug 5 is equipped with a power bandage 6 covering the end portion of the tube 1. The reciprocal part of the plug 5, brought with an interference fit into the tube 1, is made in the form of an annular groove 7 on a cylindrical surface. To increase the tightness, the width of the annular groove 7 exceeds the width of the power band 6, tightening the tube 1.

For the convenience of refueling the tube 1 with a fire extinguishing agent 2, ensuring that it can be recharged and / or pressurized with working pressure during operation, the plug 5 can be made in the form of a connecting fitting, as shown in figure 2. The plug is equipped with a threaded plug 8 and has a threaded portion 9, while the plug 8 is mounted on the threaded portion 9, and the through axial channel 10 is made in the plug 5. The threaded portion 9 of the plug 5 is made with an external thread and protrudes beyond the end of the tube 1, and in the through axial channel 10 of the plug 5 from the side of the extinguishing agent 2, a check valve 11 is installed, for example, in the form of a spring ball. The non-return valve 11 helps to prevent leakage of extinguishing agent 2 when refueling the device.

To implement a device with a forced start function, the plug 5 is equipped with a bursting disc 12, the through axial channel 10 is made with a step, on which the bursting disc 12 is installed. The bursting disc 12 is made moisture-gas-tight, mainly from fusible material.

Figure 3 presents the design with the function of the forced start by means of pyrotechnic means 13 for blasting the membrane 12. Pyrotechnic means 13 is a pyro cartridge installed in the through axial channel 10 of the plug 5 from the side of the plug 8 mounted on the threaded section 9, which is also made with the outer the thread and protrudes beyond the end of the tube 1. At the same time, the rupture disk 12 is fixed on the ledge in the through axial channel 10, for example, by the nut 14. In this design, the rupture of the membrane 12 can occur spontaneously no in case of fire under the influence of an excess pressure developed upon heating the fire extinguishing agent 2, or with a standard pyrotechnic means 13 which is triggered upon application of a pulse of electric current. The electrical contacts 15 of the pyrotechnic means 13 are connected to a fire extinguishing system power source (not shown conventionally in FIG. 3). In plug 5, holes 16 are made for passage of extinguishing agent 2 into the area of the protected object.

Figure 4 presents the design with the function of the forced start by means of the checker 17 of a flammable aerosol-forming extinguishing composition installed in the through axial channel 10 with the possibility of interaction with the bursting membrane 12. The solid fuel monolithic checker 17 is tightly pressed to the membrane 12 by a plug 8 mounted on the threaded section 9 , which in this design is made with internal thread, and the plug 8 itself is made in the form of a nut. To ignite the drafts 17, a flammable fire-resistant cord 18 is connected to it, the free end of which can be routed along the protected object with the coverage of all its fire hazard zones (in Fig. 4, the tracing is not conventionally shown).

A gas fire extinguishing device operates as follows.

The tube 1, filled with a fire extinguishing agent 2, is additionally pressurized with a small (1-3 atmospheres) nitrogen pressure and sealed with a stopper 5 and crimped with a power bandage 6 over the annular groove 7. For the design shown in Fig. 2, charging and pressurization are performed through the axial through channel 10, while the ball of the check valve 11 is pressed by its spring and does not allow the extinguishing agent 2 and nitrogen to flow out after refueling and before sealing the end with a plug 8. The device is placed on the protected object, while the pressure indicator 3 shows the total pressure of saturated refrigerant vapor and boost pressure of nitrogen. During operation of the device, the pressure indicator 3 is periodically monitored and, when it falls below the permissible value calculated taking into account the actual operating temperature, either the device is replaced or refilled.

When a fire occurs in the zone where the tube 1 is located and the wall reaches a temperature of more than 220 ° C from exposure to an open flame from the source of ignition, the material of the tube 1 softens and, under the influence of excessive pressure, a hole opens in it in the form of a nozzle through which the extinguishing agent 2 is supplied directly into the fire, eliminating it. Thus, the device is self-launched in the most general case as applied to all the described structural schemes. Self-triggering or self-starting occurs in case of inactivity of the operator, which for some reason is not provided or cannot start the fire extinguishing device.

To implement the device shown in figure 3 and 4, it is possible to force start. When signs of fire are detected (fire, smoke), the operator makes a forced start, gives a pulse with a current strength of 0.1 to 1 A from the power supply of the fire extinguishing system (not shown conventionally) to the electrical contacts 15 of the pyrotechnic means 13. The force of the flame from the pyrotechnic means 13 destroys the bursting membrane 12 and stimulates the beginning of the outflow of the gaseous extinguishing agent 2, which through the axial channel 10 enters the zone of the protected object, is sprayed, suppressing the fire, eliminates it. After the fire is extinguished, the freon evaporates. When triggered, the tube 1 does not have any harmful mechanical effect on the equipment of the protected object. In the case of the implementation of the device shown in Fig. 4, the operator sets fire, for example, through an incandescent spiral (not shown conventionally) to a flammable fire-resistant cord 18, which in turn ignites the checker 17. The force of the flame from the checker 17 destroys the bursting disc 12, and through axial channel 10 gaseous extinguishing agent 2 enters the zone of the protected object. The combustion products of the checkers 17 are also involved in extinguishing the fire. Self-ignition of the fire-resistant cord 18 is provided, trassed in places of the most likely occurrence of fire sources. With the achievement of a critical temperature value at the location of the flame-retardant cord 18, it ignites. It is also possible the destruction of the bursting membrane 12 under the action of high pressure when heated in case of fire extinguishing agent 2.

The advantage of a gas fire extinguishing device is its safety, reliability and effectiveness. The operation of such a device is not economically and technically fraught with significant costs.

The above examples of the implementation of a gas fire extinguishing device 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 (9)

1. A gas fire extinguishing device containing a tube with hermetically sealed ends filled with a fire extinguishing substance, characterized in that it is equipped with a pressure indicator in the tube containing a sensing element and a stopper with a power bandage, while the pressure indicator is mounted in the end of the tube with the possibility of interaction of its sensitive element with a fire extinguishing substance, and the cork - from the side of the opposite end of the tube so that the power bandage covers the tube, and the reciprocal part of the cork is tightened Nutri tube and is formed as an annular groove in the cylindrical surface of the tube, the width of which exceeds the width of the power band. 2. The device according to claim 1, characterized in that the pressure indicator is made in the form of a gauge arrow type. 3. The device according to claim 2, characterized in that the plug is equipped with a plug and has a threaded portion, while the plug is mounted on the threaded portion, and a through axial channel is made in the plug. 4. The device according to claim 3, characterized in that the threaded portion of the tube is made with an external thread and protruding beyond the end of the tube. 5. The device according to claim 4, characterized in that a check valve is installed in the through axial channel of the plug from the side of the extinguishing agent. 6. The device according to claim 3, characterized in that the plug is provided with a bursting disc, the through axial channel in the plug is made with a step, and the bursting membrane is mounted on the step. 7. The device according to claim 6, characterized in that it is equipped with pyrotechnic means for blasting the membrane, the threaded section of the tube is made with an external thread and protruding beyond the end of the tube, while the pyrotechnic means is installed in the through axial channel of the tube from the side of the plug. 8. The device according to claim 6, characterized in that the cork is equipped with a block of flammable aerosol-forming extinguishing agent installed in a through axial channel with the possibility of interaction with a bursting disc. 9. The device according to claim 8, characterized in that it is equipped with a flammable fire-resistant cord connected to the saber.

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