RU164658U1 - FIRE EXTINGUISHING INSTALLATION - Google Patents

Abstract

A fire extinguishing installation, including a mounting frame, a gas turbine engine consisting of a compressor, a combustion chamber and a turbine having stages, and an output nozzle, a gas turbine engine fuel system mechanically connected to the engine, an electric generator and high, medium and low pressure water pumps, a storage tank for a liquid, an associated water intake device connected to a low pressure pump, a fire barrel made in the form of a gas-dynamic nozzle connected to a mixing chamber, is intended designed for mixing the liquid and the gas working fluid and connected to the inlet of the fluid supply, its rotation drive, a control system that is connected to the rotation drive of the fire barrel and the electric generator, pipelines, a foaming device connected by a pipeline to the mixing chamber of the liquid and gas working fluid, the output of the gas working fluid of the compressor of the gas turbine engine is connected to the mixing chamber of the fire barrel, characterized in that it is provided with an additional output of the gas working fluid, you olnennym between the turbine stages and the associated operating gas outlet of the compressor body.

Description

The proposed utility model relates to fire extinguishing devices, namely, devices operating autonomously and in which it is possible to use the technology of producing highly concentrated jets having a long range and a finely divided droplet composition.

The proposed fire extinguishing installation can be used to extinguish peat bogs, forest fires, etc., because its design provides an increase in the speed of the extinguishing jet, thereby increasing the quenching properties of the jet, namely, allows a deeper penetration of the working fluid inside the burning layer.

A fire-fighting installation is known, containing a pontoon with a rigidly fixed support column, on which a barrel is installed to create a directed water flow, a fire pump with an independent drive and pipelines connecting the water inlet to the pump inlet and the barrel with the pump outlet (SU 1602553 according to class A62C 29/00, 1990).

The pump unit is mounted on a platform mounted inside the pontoon with the possibility of rotation in a plane parallel to the axis of the support column.

The known design allows you to expand the transport capabilities of the fire fighting installation, and to extinguish various fires using outboard water.

However, the area of its use is limited by the low maximum possible range of the water jet supply, determined by the pressure of the liquid at the entrance to the barrel, i.e. the capabilities of the fire pumping unit, and the height of the gun barrel.

With a high fire intensity, a floating installation cannot be brought close enough for effective fire fighting to be safe.

The limitation of the range of supply of the liquid jet during extinguishing, for example, oil and gas fountains at offshore gas and oil production and production facilities, necessitates the use of an additional cooling system for the design of the fire fighting installation.

In addition to the insufficient flight range of the water jet directed to the fire source, the well-known fire extinguishing installations that are part of fire vessels have large losses in pump performance associated with the need to create a water curtain around the vessel, high metal consumption of pressure pipelines and high operating costs.

The closest in technical essence to the proposed solution is a fire extinguishing installation, including a mounting frame, a gas turbine engine, consisting of a compressor, a combustion chamber, a turbine having steps and an outlet nozzle, its fuel system, mechanically connected to the engine, an electric generator and high, medium sized water pumps and low pressure, a storage tank for liquid, an associated water intake device made in the form of a receiving sleeve connected to a low pressure pump, a rotary a barrel made in the form of a gas-dynamic nozzle connected to a mixing chamber designed to mix a liquid and a gas working fluid and connected to a fluid supply inlet and having a gas working fluid supply inlet, a control system that is connected with a fire barrel rotation drive and an electric generator, pipelines , a foaming device connected by a pipeline to its supply unit in a chamber for mixing a liquid and a gas working fluid of a fire barrel (RF patent No. 2236876 for cl. A62C 3/00, 2004).

The disadvantages of the known installation are:

- low profitability due to the low efficiency of the use of a gas turbine installation, because the air used in the fire system, taken from the main compressor or from the additional compressor, does not perform expansion work on the turbine;

The heat contained in the air after the compressor (the air temperature after the compressor can be on the order of 500-700 K) is irretrievably lost, heating the water, and with it is released into the atmosphere. Heat lost from the engine nozzle is also lost;

The above disadvantages do not allow the use of such installations for extinguishing fires with high radiation intensity, fires in high-rise buildings, etc., because a large flow rate of the working fluid is required to create a jet range, which in turn ensures the safety of the installation itself.

The technical result solved by the proposed utility model is the creation of a fire extinguishing installation, which allows to increase the flow rate of the working fluid used to create a gas-droplet jet with the same amount of fuel consumed.

The technical result in the proposed utility model is achieved by creating a fire extinguishing installation, including a mounting frame, a gas turbine engine consisting of a compressor, a combustion chamber and a turbine having stages, and an output nozzle, a gas turbine engine fuel system mechanically connected to the engine, an electric generator and high water pumps, medium and low pressure, a storage tank for a liquid, an associated water intake device connected to a low pressure pump, a fire barrel made in the idea of a gas-dynamic nozzle connected to a mixing chamber intended for mixing a liquid and a gas working fluid and connected to a fluid inlet, a drive for turning it, a control system that is connected with a turning drive for a fire barrel and an electric generator, pipelines, a foaming device connected by a pipeline to the camera mixing liquid and gas working fluid, while the output of the gas working fluid of the compressor of the gas turbine engine is connected to the mixing chamber of the fire barrel, which but useful model is provided with an additional output of the gas working fluid formed between the turbine stages and the associated operating gas outlet of the compressor body.

The use in the proposed installation of a gas turbine engine, which is a source of power, allows you to get a high-energy gas working fluid in the form of compressed air.

The gas working fluid is obtained by joint selection of a portion of compressed air from the compressor and between the stages of the compressor turbine.

In this case, it is possible to additionally use part of the gases exhausted at the first stage of the turbine.

The proposed fire extinguishing installation is illustrated by the following construction description and drawing, which shows a fire extinguishing installation diagram.

The fire extinguishing installation includes a mounting frame 1, a gas turbine engine, consisting of a compressor 2, a combustion chamber 3 and turbines having stages 4 and 5, and an output nozzle 6, a fuel system 7 of a gas turbine engine mechanically connected to the engine, an electric generator 8 and high-pressure water pumps 9, medium 10 and low 11 pressures, a storage tank 12 for liquid, an associated water intake device connected to a low pressure pump Pi fire barrel with a drive 13 of its rotation.

The fire barrel is made in the form of a gas-dynamic nozzle 14 connected to a mixing chamber 15 for mixing liquid and a gas working fluid, and it has an inlet 16 for supplying liquid.

The fire extinguishing installation also has a control system 17, which is connected with an electric generator 8, a foaming device 18, connected by a pipeline to the mixing chamber 15 of the liquid and the gas working fluid.

At the same time, the output 19 of the gas working fluid of the compressor 2 of the gas turbine engine and the additional output 20 of the gas working fluid made between the turbines 4 of the first stage and 5 of the second stage are connected to each other and to the mixing chamber 15 of the fire barrel. Air from the compressor 2 and the turbines enters through line 21 into the mixing chamber 15, where it is mixed with water supplied by a high pressure pump 9 to obtain a dispersed gas-droplet stream.

From the space between the turbines 4 of the first stage and 5 of the second stage, combustion products are taken after the first stage of the turbine. The pressure and temperature of these combustion products are comparable with the parameters of the air taken from the compressor 2. Thus, the flow rate of the working fluid used to create a gas-droplet jet is increased.

Since the release of extinguishing fluid from the fire barrel is accompanied by the appearance of an appropriate reactive force, to compensate for it, the outlet openings of the nozzles of the gas turbine engine and the fire barrel are directed in opposite directions,

The fire barrel can be installed separately from the mounting frame 1, depending on the installation conditions on the carrier vehicle, stationary installation, ships, etc.), but it is necessary that it is connected by a pipeline to a high-pressure pump 9, an engine compressor 2 and a barrel rotation drive 13.

It is known that the smaller the droplet size has a dispersed flow, the higher the liquid velocity can be obtained at the exit of the gas-droplet nozzle and, therefore, the greater the range of the jet, ceteris paribus, and the improvement of the quenching properties of the jet, since smaller droplets evaporate faster.

The water intake device is made in the form of a receiving sleeve 22 connected to a low pressure pump 11 connected to a gas turbine engine and connected to a storage tank for liquid 12.

The foaming device 18 is connected to the chamber 15 for mixing the liquid and gas of the fire barrel, made in the form of a container with a foaming agent.

The work of the proposed fire extinguishing installation is as follows:

Pre-stand-alone installation is prepared for work, filling the tank 18 with a foaming agent, and the tank 12 with liquid. They fix it on a transport medium, for example, a helicopter and deliver it to the fire extinguishing zone. The installation is placed at the required distance from the fire.

Then start the gas turbine engine, which drives the high pressure pump 9, the generator 8.

The high pressure pump 9 through the pipelines delivers the extinguishing fluid from the liquid storage tank 12 to the liquid and gas mixing chamber 15, and the air compressor 23 also supplies the compressed air necessary for dispersing the liquid. In this case, part of the compressed air comes from the compressor 2 and the turbines pass through the line 21 into the mixing chamber 15, where it is mixed with water supplied by a high pressure pump 9 to obtain a dispersed gas-droplet stream.

In the mixing chamber 15, a gas-droplet stream is formed, which accelerates to a working speed in the gas-dynamic nozzle 14.

In order to maximize coverage of the fire zone using the control system of the installation 17 and the drive turn 13 of the fire barrel, it is rotated in horizontal and vertical planes.

In the case of extinguishing flammable liquids, a foaming agent is used, with which a container 18 is filled.

Mixing with the extinguishing liquid, the foaming agent creates foam at the exit of the fire barrel, which covers the fire, stopping the flow of oxygen necessary for combustion.

When using the entire supply of extinguishing liquid in the storage tank 12, it is possible to fill it with an additional amount of liquid from an external source, for example, a reservoir or tanker.

The proposed fire extinguishing installation was tested and the following results were obtained. Used a gas turbine engine with parameters: gas flow rate G = 9 kg / s

compressor compression ratio π = 9

gas temperature in front of the turbine 4 T = 1190 K

Energy losses in the form of heat when using an engine with these parameters are reduced by 7%.

Claims (1)

A fire extinguishing installation, including a mounting frame, a gas turbine engine consisting of a compressor, a combustion chamber and a turbine having stages, and an output nozzle, a gas turbine engine fuel system mechanically connected to the engine, an electric generator and high, medium and low pressure water pumps, a storage tank for a liquid, an associated water intake device connected to a low pressure pump, a fire barrel made in the form of a gas-dynamic nozzle connected to a mixing chamber, is intended designed for mixing liquid and gas working fluid and connected to the fluid supply inlet, its rotation drive, a control system that is connected to the fire barrel rotation drive and electric generator, pipelines, a foaming device connected by a pipeline to the mixing chamber of the liquid and gas working fluid, the output of the gas working fluid of the compressor of the gas turbine engine is connected to the mixing chamber of the fire barrel, characterized in that it is provided with an additional output of the gas working fluid, you olnennym between the turbine stages and the associated operating gas outlet of the compressor body.

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