RU192652U1 - FIRE EXTINGUISHING INSTALLATION - Google Patents

Abstract

The utility model relates to the field of fire extinguishing, and more specifically, to stationary controlled installations for automatic detection and suppression of fires in guarded premises. The fire extinguishing installation contains strain gauge modules with pressure functional fluid located on weighing platforms, equipped with a locking and starting device that are mounted using quick-disconnect clamps on a frame frame made of perforated U-shaped battens and equipped with a siphon tube connected to a common collector, a launch lock and a monitor, while the shutter-starting device of the first module connected to the electric starter is connected in series through pneumatic tubes to the pneumatic starters of the shutter-starting devices of the remaining modules in a single system. whose diameter is determined by the ratio: D / d = 9-12, where D is the diameter of the tube channel and d is the diameter of the drainage hole. The proposed technical solution provided an increase in the functional the reliability of the system, interlocked from the associated fire extinguishing modules, having a greater filling with a working fluid, which is cumulatively discharged into the ignition area to suppress it.

Description

The utility model relates to the field of fire extinguishing, and more specifically, to stationary controlled installations for automatic detection and suppression of fires in protected premises.

The level of this technical field is characterized by a variety of fire extinguishing installations described in patents No. 2600910 "Volumetric fire extinguishing system in electric train cars", А62С 13/22; No. 2295991 “Fire extinguishing system in high-rise buildings, structures”, А 62С 35/00, 37/00; No. 2225733 “Fire extinguishing system of a multi-storey car storage”, А62С 37/00, each of which contains modules (generators) distributed in the guarded room, equipped with a pyrotechnic bomb, generating a gas-aerosol fire extinguishing mixture, the ignitor of which is initiated from an external control unit associated with sensors standard fire alarm.

A common drawback of the described installations is their one-time operation, because equipped modules, when functioning as intended, burn out, which requires additional capital investments for restoration.

In addition, regular monitoring of functionality and routine maintenance of autonomous modules distributed in a secure room is costly and difficult.

The noted shortcomings were eliminated in the fire extinguishing installation (see www.npo-pass.com | PDF | MPG.pdf), which was selected as the closest analogue of the proposed installation due to its technical nature and the number of matching features.

The known fire extinguishing installation contains modules, filled with functional liquid under pressure, compactly mounted on a frame frame of perforated U-shaped rails, and which are equipped with locking and starting devices (ZPUs) connected to a common manifold covered by automatic valves.

The ZPU of one of the modules is connected to the automatic electromagnetic starter initiated from the control unit, and to the ZPU of the remaining modules - through pneumotubes into the general system of the extinguishing mixture.

The modules are placed on weighing platforms of strain gauge, connected with the indicating device, and by means of quickly detachable clamps are fixed on the rails of the frame.

In the well-known reusable installation, the modules are grouped compactly and accessible on a common frame, which is convenient for maintenance, monitoring and commissioning, the modules operate in parallel, providing high performance generation of a functional hydrosol and fire fighting efficiency.

However, the known installation is characterized by an inherent disadvantage - the limitation of the supply and discharge of the quenching generated by the action of the hydrosol due to the excess pressure in the module of the vaporized gas above the working fluid mirror, which reduces the possible charge amount, which forces the use of an additional reserve module in the system for the required discharge volume extinguishing hydrosol. This increases the occupied floor space and capital investment in the fire safety structure.

The technical problem, the solution of which the present utility model is aimed at, is to increase the functional reliability and efficiency of the intended purpose of the proposed installation.

The required technical effect is achieved by the fact that in a known fire extinguishing installation containing strain gauge modules with functional liquid under pressure placed on weighing platforms, equipped with a locking and starting device, which are mounted by means of quick-detachable clamps on a frame frame of perforated U-shaped rails and equipped with a siphon a tube connected to a common collector, a start block and a monitor, while the locking and starting device of the first module is connected to the electric starter it is connected through a pneumatic tube to the pneumatic actuators of the locking and starting devices of the remaining modules in a single system, at the suggestion of the author, in the siphon tube of each module a drainage hole is made above the liquid filling mirror, the diameter of which is determined by the ratio: D / d = 9-12, where D is the diameter tube channel, ad is the diameter of the drainage hole.

Distinctive features of the proposed technical solution have provided an increase in the functional reliability of the system interlocked from the associated fire extinguishing modules, which have a greater filling with a working fluid, which, in aggregate, is sufficiently discharged into the fire source for guaranteed suppression of the fire. At the same time, the technical effect of the proposed technical modernization of the design of the modules of the fire extinguishing installation consists in reducing its dimensions and the occupied production area, in comparison with the prototype of the equal productivity of extinguishing agent generation.

The implementation in the siphon tubes of each module of the drainage holes above the mirror of the functional fluid is aimed at automatically displacing part of the evaporating carrier gas from the volume above the liquid filling, which in this case increases accordingly, which creates an additional supply of extinguishing agent in the fire extinguishing system and, as a result, increases productivity by generating an extinguishing hydrosol at the installation outlet.

The ratio of the diameter of the channel of the siphon tube to the diameter of the drainage hole (D / d) was optimized by calculation using the mathematical model of the experimental design to accelerate the refueling of the module with a high-volume fire extinguishing agent, which was tested on a prototype.

When the ratio of the diameter of the channel of the siphon tube to the diameter of the drainage hole (D / d) is less than 9, the effect of accelerating the filling of the module with a liquefied extinguishing agent practically does not degenerate and there is no noticeable mass increase.

When the ratio of the channel diameter of the siphon tube to the diameter of the drainage hole (D / d) is greater than 12, the release of the functional fluid is inhibited due to its partial overflow from the drainage hole of the siphon tube to the module filling mirror, which reduces the overall fire extinguishing efficiency of the installation.

Therefore, each essential sign is necessary, and their combination is sufficient to achieve the desired result in solving the problem, that is, not the sum of the effects is obtained, but a new super-effect of the sum of the signs.

The utility model is illustrated by drawings, which do not limit the scope of claims of the totality of the features of the formula, but have a purely illustrative purpose.

The drawings show:

in FIG. 1 - general view of a fire extinguishing system, isometry;

in FIG. 2 - the mount of the clamp on the rail of the frame;

in FIG. 3 is a section along AA in FIG. 2.

Installation according to the proposed utility model (Fig. 1) contains a group of modules 1 mounted on a stationary frame of perforated rails 2 of a U-shaped profile.

Modules 1 are installed on weighing platforms 3 strain gauge, which are electrically connected to the indicator device 4, mounted on the rack 5 of the frame.

Each module 1 installation quickly detachable clamps 6 mounted on the rails 2 of the frame.

The collar 6 (Fig. 2) is rigidly connected to the perforated carriage 7 of the U-shape, counter-mounted inside the rail 2 of the frame with a guaranteed structural backlash "h" vertically to the side (Fig. 3), where it is locked in geometric closure with the rail 2 by staples 8, which is installed in their coaxial perforations, thus preserving the possibility of movement of the carriage 7 along the guides of the staples 8 relative to the rail 2.

In this case, the relative position and the rigid connection of the clamp 6 with the module 1 remains unchanged.

The modules 1 of the fire extinguishing installation (Fig. 1) are equipped with pneumatic locking and starting devices 9, pneumatic actuators 10 of which are connected to the common collector 11 of the high-pressure working gas (carbon dioxide, chladones) and between each other - pneumatic tubes 12 of the communication in the jet system of the fire extinguishing hydrosol.

The first module 1 in the drawing is equipped with an electromagnetic starter 13 connected to the control unit 14.

The locking-starting device 9 of each module 1 is connected with its siphon tube 15 for supplying the functional fluid to the bottom, while in the volume of module 1 a back-up is created on the mirror 16 of the functional fluid 17 from above by the pressure of the vaporizing gas.

Under the action of excess pressure above the mirror 16 of the functional fluid 17, the gas through the drainage hole 18 enters the siphon tube 15 and then by bubbling into the free volume of the module 1, while the mass of the injected functional fluid 17 increases by 16-18%.

The communication of the displaced compressed air in the container of module 1 from the volume above the mirror of the fire extinguishing agent through the drainage hole 18 in the siphon tube 15 with its bottom allows automatic mass cycling of compressed air to increase the mass of the process fluid 17 poured into the additional space released.

For the effective operation of the self-regulating system for controlling the level of the refilled liquid 17 into module 1, for dynamic circulation of compressed air in automatic mode with bubbling through the mass of liquid 17, a drain hole with a calculated diameter in the range of 1.5-2.0 is made in a siphon tube 15 with a diameter of 18 mm mm

The control of the filling of the modules 1 is carried out on the monitor of the device 4, which captures the linear draft of the weighing platform 3, calibrated by the filled mass of the functional fluid 17, and closes the loading valve (not shown conditionally) on the manifold 11.

The described structural connection of each module with the supporting frame allows the carriages to move vertically along the fixing brackets, with independent vertical autonomous movement of the modules mounted on weighing platforms relative to the stationary frame, which ultimately gives objective information about the degree of filling with functional fluid of each module, which is visualized on monitor, which displays the current weight indicators of the modules, the results of which judge their readiness for work as intended and but topping is carried desired functional fluid to the maximum possible level when the service ohranenii.

The fire extinguishing installation operates as follows.

Upon receipt of a signal from the temperature rise and / or smoke detector of the standard fire system in the protected room, a command is sent to the control unit 14 to the electromagnetic starter 13 of the first module 1, which will switch the locking and starting device 9, connecting the siphon tube 15 to the collector 11 and sequentially through pneumatic tubes 12 with pneumatic actuators 10 of the remaining modules 1 to start them, and also opens the exhaust valve of the collector 11, through which a fire extinguishing hydrosol is discharged into a fire center Niya, suppressing it.

After completion of the fire extinguishing installation, a technological audit and refueling of modules 1 is carried out for re-security of the premises as intended.

Tests of the prototype of the proposed fire extinguishing installation have confirmed the achievement of higher levels of functionality and purpose, then it can be recommended for serial production for delivery to customers.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which e does not explicitly follow for a specialist in automatic fire extinguishing means, showed that it is unknown, and taking into account the possibility of industrial serial production of the installation using a utility model in an existing production, we can conclude on compliance with the conditions of patentability.

Claims (1)

A fire extinguishing installation, comprising strain gauge modules with functional fluid under pressure placed on weighing platforms, equipped with a locking and starting device, which are mounted using quick-release clamps on a frame frame of perforated U-shaped rails and equipped with a siphon tube connected to a common collector, a launch unit and a monitor, while the locking and starting device of the first module connected to the electric actuator is connected in series through the pneumatic tubes to the pneumatic actuators -starting devices of the remaining modules into a single system, characterized in that in the siphon tube of each module a drainage hole is made above the liquid filling mirror, the diameter of which is determined by the ratio: D / d = 9-12, where D is the diameter of the channel of the tube and d is the diameter drainage holes.

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