RU140545U1 - INSTALLATION OF GAS EXTINGUISHING OF OIL PRODUCTS WITH A FLOATING PLATE IN VERTICAL STEEL TANKS - Google Patents

Abstract

Gas extinguishing installation of oil products with a floating plate in vertical steel tanks, characterized in that the gas pipe inside the tank is rigidly connected with a flexible metal sleeve to the wiring pipe with a check valve and gas nozzles, which is mounted on the floating plate, while the floating plate is mounted due to the internal openings to a stationary support pipe connected to the roof and bottom of the tank and vertically moves through the pipe due to a change in the level of oil in ervuare, and in that the gas supply to the gas pipeline is applied isothermal unit, and an extinguishing agent, carbon dioxide is used.

Description

The proposed utility model relates to extinguishing oil products, and can be used in the oil industry to extinguish fires of oil products in vertical steel tanks (RCS) of large capacity. The proposed utility model is most applicable for extinguishing oil products at oil depots and fuel depots.

Known vertical cylindrical steel tank for petroleum products [1]. This tank has a bottom, a wall and a fixed roof. For receiving and dispensing petroleum products, reservoirs of this type have acceptance pipes. From the outside, valves are connected to them. In order to provide “small” and “large” tank breaths, there is a breathing valve. A metering hatch is installed on the roof of the tank, which serves to measure the level and take samples of petroleum products.

In order to protect the tank from flash or explosion in the presence of fire, a fire fuse is installed under the breathing valve. Also on the tank there are monitoring and signaling devices (level gauges, samplers, level indicators, fire fighting devices) and other equipment (manhole, ventilation pipes, safety valves). In accordance with the requirements, surface tanks for storing oil and oil products with a volume of 5000 m ³ and more are equipped with automatic fire extinguishing systems. In warehouses of the third category, if there are no more than two ground tanks with a volume of 5000 m ^{3, it is} possible to extinguish these tanks with mobile fire equipment, provided the tanks are equipped with stationary foam generators (foam chambers, foam nozzles) and special pipelines discharged for deboning [2]. Extinguishing fires using foam can be done in two ways:

1. The filing of medium-frequency foam on top of the tank on a layer of burning oil.

2. The supply of foam of low multiplicity under the layer of oil.

Foam fire extinguishing installations of medium multiplicity from the top of the tank to the oil product layer in most cases do not provide fire extinguishing in the initial stage due to damage to the foam injection nodes from the primary explosion.

Also known is a vertical steel tank for oil and oil products with a volume of 5000 m ³ , equipped with a sub-layer extinguishing unit [3]. The sublayer extinguishing installation of the tanks contains a foam conduit with a wiring, valves, a foam generator, a safety membrane, a check valve. The sublayer extinguishing method is associated with the use of special types of foaming agents, which form a foam, mixes little with oil and oil products, and form water films that spontaneously spread on the surface of the fuel. Foaming jet, getting into the oil, due to lower density floats to a burning surface. At the same time, the rise of the foam depends on the height of the level of oil and oil product. The height of the tank with a capacity of 5000 m ³ depending on the diameter is from 12 to 15 meters.

The disadvantages of installing a sublayer quenching of oil products in tanks are:

1. Deterioration of the quality of petroleum products when passing through their layer of foam jet.

2. The presence of a certain temporary period of foam rising to the surface of the oil product, which leads to an increase in the area of the fire and an increase in material damage.

3. The inability to use liquefied gas to extinguish.

Also known is the installation of sublayer quenching of oil products with a floating plate moving vertically along the support pipe [4].

In this installation, the tank has standard equipment. A foam conduit equipped with valves, a non-return valve, an electromagnetic valve, with a manual opening and closing device, a communication line and a starting device, as well as a foam generator is supplied to the tank.

In this case, the foam conduit is rigidly connected with a metal flexible sleeve to the wiring conduit with a check valve and foam nozzles. The wiring is connected to a floating plate, which is mounted by means of an internal hole on a stationary support pipe connected to the roof and bottom of the tank. Check valves are designed to prevent oil from entering the wiring, flexible metal sleeve and foam.

The floating plate moves vertically in the upper fuel layer through the pipe due to a change in the level of oil in the tank.

In order to strengthen the design of the tank, the support pipe is rigidly connected by trusses to the side walls of the tank.

Installation works as follows. Through the inlet pipe, the pipeline and the corresponding valve, the oil enters the tank. A layer of oil is formed in the reservoir. In case of ignition of the fuel, the foaming agent solution is supplied to the reservoir using a stationary source or a mobile tanker. At the same time, the valves, check valve, solenoid valve of the foam pipe open. The foaming solution passes through the foam generator and enters the metal flexible sleeve, piping and wiring. After this, the check valve opens, and the foam stream through the foam nozzles enters the upper layer of the oil product. Then, due to the lower density, the foam jet enters the surface of the fuel and lubricant and forms a foam layer above the level of the burning oil product. As a result of the formation of a foam layer and the cessation of access to air oxygen, the fire stops.

The disadvantages of installing a sublayer quenching of oil products with a floating plate moving vertically along the support pipe:

1. The inability to use liquefied gas to extinguish a fire.

2. Insufficient foam resistance at elevated temperatures. Carbon dioxide is used to extinguish fires in enclosed spaces. It is heavier than air. Its density is 1.839 kg / m ³ at 20 ° C. Its liquefaction temperature is minus 78 ° C. In this case, the gas immediately crystallizes into a solid. In the liquid state, carbon dioxide is found only at high pressures. Moreover, the density of the liquid, depending on temperature and pressure, can be 771-925 kg / m ³ .

A system for suppressing carbon dioxide of large, complex fires in a confined space is described [5].

This system has an isothermal tank with liquid carbon dioxide, a means for moving an isothermal tank, a gasifier, a device for supplying a heat carrier to a gasifier heat exchanger, and means for supplying gas to a fire source. As a heat carrier, steam or hot water is used.

The system operates as follows. A container of carbon dioxide is transported to the site of the fire. Liquid carbon dioxide enters the gasifier, where the heating medium is electrically heated. In connection with heating, liquid carbon dioxide is converted to carbon dioxide. Carbon dioxide from the gasifier through the means of supply enters the fire.

The disadvantages of the carbon dioxide suppression system of large, complex fires in a limited space are:

1. Low efficiency in extinguishing oil product fires in tanks. High fire hazard system.

2. The use of electric heating.

3. The need for delivery to the place of fire.

The closest in technical essence of the proposed utility model is the installation of gas fire extinguishing based on an isothermal module for liquid carbon dioxide [6].

In this installation, the tank has standard equipment. A main pipeline equipped with a locking and starting device is supplied to the reservoir.

In this case, the main pipeline is connected to the inner annular pipeline, which is located in the upper zone of the tank. On the annular pipeline inside the tank, nozzles for the release of gas are installed. The main pipeline is also connected to an isothermal module for liquid carbon dioxide (MIZU).

Installation works as follows. Through the inlet pipe, the pipeline and the corresponding valve, the oil enters the tank. A layer of oil is formed in the reservoir. When a fuel ignites, liquid carbon dioxide is supplied to the reservoir by opening the shut-off and starting device from the isothermal module. Carbon dioxide enters the main pipeline, then the annular pipeline and nozzles. By reducing the pressure in the pipelines, liquid carbon dioxide turns into a gaseous state. After passing the nozzles, gaseous carbon dioxide enters the upper part of the tank. Then, due to the higher density than the vapor-air mixture of the oil product, carbon dioxide falls to the surface of the fuel and lubricant and forms a gas layer above the level of the burning oil product. As a result of the formation of a gas layer and the cessation of access to air oxygen, the fire stops.

The disadvantages of a gas fire extinguishing installation based on an isothermal module for liquid carbon dioxide are:

1. The installation in most cases does not provide fire extinguishing in the initial stage due to damage to the gas supply nodes from the initial explosion of the vapor-air mixture.

2. High consumption of carbon dioxide to extinguish and fill the annular pipeline.

The proposed utility model allows us to solve the problem of increasing the efficiency of extinguishing fires in vertical steel tanks designed for receiving, storing and dispensing petroleum products.

The solution to this problem is achieved by the fact that the gas pipe inside the tank is rigidly connected with a flexible metal sleeve to the wiring pipe with a non-return valve and gas nozzles, which are mounted on a floating plate, while the floating plate is mounted on the supporting stationary pipe connected to the roof due to an internal opening and the bottom of the tank and vertically moves through the pipe due to changes in the level of oil in the tank, as well as the fact that isothermal gas is used to supply gas to the pipeline cue module, and is used as an extinguishing agent of carbon dioxide.

These signs are essential for solving the utility model problem, since the efficiency of extinguishing oil products in large-capacity storage tanks increases due to the reduction of fire extinguishing times, the loss of oil products from combustion and the quality of fuels and lubricants are minimized, and the reliability of the installation is increased.

The essence of the utility model is illustrated by drawings (Fig. 1, Fig. 2, Fig. 3), which depict: the tank in the context in the initial and working position, as well as a section of the support pipe with a floating plate.

In FIG. 1, 2 shows a tank 1 having a receiving pipe 2 and a pipe 3, a valve 4, a breathing valve 5, a metering and light hatches 6, 7, a ventilation pipe 8, a manhole 9, a gas pipeline 10, equipped with a valve 11, a check valve 12, a locking-starting device 13, with a communication line 14 and a starting device 15. An isothermal module 16 with liquid carbon dioxide 17 is connected to the gas pipeline.

The gas pipe 10 is rigidly connected by a metal flexible sleeve 18 to the pipe 19 of the wiring 20 with a non-return valve 21 and nozzles for discharging gas 22. The wiring is connected to a floating plate 23, which is mounted by means of an internal opening 24 on a stationary support pipe 25 connected to the roof and the bottom of the tank . Check valves are designed to prevent oil from entering the wiring, flexible metal sleeve and gas pipeline.

The floating plate moves vertically in the upper layer of fuel 26 through the pipe by changing the level of oil in the tank.

In order to strengthen the design of the tank, the support pipe is rigidly connected by trusses 27 with the side walls of the tank.

Liquid carbon dioxide, which is stored in an isothermal module under pressure, is used as a fire extinguishing agent. When the locking and starting device is opened, carbon dioxide enters the gas pipeline. By reducing the pressure in the gas pipeline and in a metal flexible sleeve on the nozzles for the release of gas, carbon dioxide passes into a gaseous state. Due to the lower density than that of the oil product, gaseous carbon dioxide comes to the surface of the fuel and lubricant material and enters the combustion zone, displacing air oxygen from it and forming a gas layer. As a result, combustion stops.

The utility model works as follows. Through the inlet pipe 2, the pipeline 3 and the corresponding valve 4, the oil product enters the tank. A layer of oil product 26 is formed in the tank. Upon ignition of combustible carbon dioxide from the isothermal module 16, it is supplied to the tank. This opens the valve 11, the check valve 12, the locking and starting device 13 of the pipeline 10. Carbon dioxide enters the metal flexible sleeve 18, the pipe 19 and the wiring 20. After that, the check valve 21 opens and the carbon dioxide through the nozzles for the release of gas 22 enters the upper layer of the oil product 26. Then, due to the lower density, carbon dioxide in the gaseous state comes to the surface of the fuel and lubricant and forms a gas layer 28 above the level of the burning oil product. As a result of the formation of a gas layer and the cessation of access of air oxygen to the combustion zone, the fire ceases.

In case of high temperature, smoke and the inability of the operator to work near the tank, the locking and starting device is opened using an electric motor. For this, the operator includes a starting device 15. It should be noted that the proposed utility model is reliable in operation and allows you to extinguish the fire in a shorter time, minimize both the loss of quality of the oil product and the amount of combusted fuel, as well as reduce the consumption of carbon dioxide.

Literature

1. Zaichenko V.N. The operation of military depots and fuel bases. M .: TsNIITEneftekhim, 2004 - 420 s.

2. Guidelines for extinguishing oil and oil products in tanks and tank farms. - M. GUGPS, 1999.

3. Sharovarnikov A.F., Molchanov V.P., Voevoda S.S., Sharovarnikov S.A. “Extinguishing fires of oil and oil products”: second edition, Fire Science, 2007 - 379 p.

4. Matveev Yu.A., Butuzov A.A., Mulgachev A.Yu. Utility Model Patent No. 120696. Installation of sublayer quenching of oil products with a floating plate moving vertically along the support pipe. M .: FIPS. 09/27/2012

5. Maslennikov VV Utility Model Certificate No. 34385. A carbon dioxide suppression system for large, complex fires in a confined space. M .: FIPS. December 10, 2003

6. Merkulov V.A., Kuzmenko K.P., Kirsanov A.I. Carbon dioxide extinguishing of fires in vertical steel tanks with oil and oil products. NTZH Fire and explosion safety №3. 2013.

Claims (1)

Installation of gas extinguishing of oil products with a floating plate in vertical steel tanks, characterized in that the gas pipe inside the tank is rigidly connected with a flexible metal sleeve to the wiring pipe with a check valve and gas nozzles, which is fixed on the floating plate, while the floating plate is mounted due to the internal openings to a stationary support pipe connected to the roof and bottom of the tank and vertically moves through the pipe due to a change in the level of oil in ervuare, and in that the gas supply to the gas pipeline is applied isothermal unit, and an extinguishing agent, carbon dioxide is used.

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