RU2849529C1 - Method for obtaining self-expanding gas-aerosol-filled foam and device for its implementation - Google Patents

Abstract

FIELD: firefighting.

SUBSTANCE: group of inventions relates to the field of foam fire extinguishing, namely to a method for producing self-foaming gas-aerosol-filled foam and to a device for producing self-foaming gas-aerosol-filled foam. The method includes pulsed mixing of a concentrated solution of a foaming agent with water simultaneously throughout the entire volume of the container and saturation of the finished solution of the foaming agent through a bubbler with gaseous and solid combustion products of an aerosol-forming composition as a result of the accumulation of excess pressure, the activation of membrane-rupture devices, and obtaining self-foaming gas-aerosol-filled foam at the outlet pipe, wherein the method is carried out using a device for obtaining self-foaming gas-aerosol-filled foam, in which the concentrated solution of the foaming agent is stored in a separate sealed container inside a sealed container with water, wherein the ready-made foaming agent solution is produced in pulses for up to 1 second by mixing the concentrated foaming agent solution with water as a result of the first membrane rupture device being activated when the pressure rises to 0.8-1.2 MPa, and then, as a result of an increase in pressure and the activation of the second diaphragm rupture device on the outlet pipe of the container due to the pressure difference, a self-foaming gas-aerosol-filled foam is obtained as a result of desorption.

EFFECT: increased efficiency and speed of obtaining self-foaming gas-aerosol-filled foam.

2 cl, 1 dwg

Description

The invention relates to the field of foam fire extinguishing, namely to extinguishing fires in tanks containing oil and oil products with a volume of up to 100,000 ^m3 : vertical steel tanks with a fixed roof without a pontoon, vertical steel tanks with a fixed roof with a pontoon, vertical steel tanks with a floating roof.

Oil and petroleum product storage tanks are among the most dangerous objects. This is due to a number of unresolved causes, leading to fires that cause significant damage to operating facilities.

In tank farms, existing fixed fire protection systems for vertical steel tanks do not provide sufficient protection, let alone rapid fire suppression. Most tank fires begin with an explosion of a vapor-air mixture. This explosion leads to the roof being blown off, which results in the failure of these systems at the initial stage of the accident: in 75% of cases, foam generators failed, and in 25%, the supply pipes failed. Only by using mobile firefighting and other equipment were fires on tanks with the most severe accident consequences extinguished.

An analysis of statistics on fires in oil and petroleum product storage tanks has shown that modern fire extinguishing systems cannot deliver foam with the required intensity.

The data showed that a large number of suppression efforts were unsuccessful, even though the fire suppression systems met or exceeded the foam intensity and dwell times prescribed by industry standards.

A device for producing self-foaming gas-filled foam is known (patent RU 2622815 C1, IPC A62C 5/02 (2006.01), published on 20.06.2017).

The essence of this technical solution is that in a device for producing self-foaming gas-filled foam, which includes a sealed container, a gas-generating device with a solid propellant charge, a system of pipelines and supply pipes, the gas-generating device is provided with a charge of an aerosol-forming composition, is installed in the upper part of the container and is provided with a gas-supply pipe with an external heat-protective coating, in the lower part of the gas-supply pipe a conical diffuser of aerosol products of combustion of the charge with radial holes is installed, ensuring their outflow into the lower part of the container and bubbling of the foaming agent solution with saturation of the solution with a fire-extinguishing aerosol, and the generator of the gas-generating device is made in the form of a set of aerosol generators, consisting of two or more generators, having separate combustion chambers with gas-supply pipes and switched on simultaneously, sequentially or in groups in accordance with the required intensity of supply of the foaming agent solution to the source of combustion.

A drawback of this technical solution is that, according to the regulatory document (clause 5.14 of GOST R "Impulse Fire Extinguishing Systems for Delivering Self-Foaming Gas-Aerosol-Filled Foam" (currently undergoing approval by the State Standard), the systems must be designed with separate compartments for the foam concentrate and water. During prolonged storage of the prepared foam concentrate solution in the container, it disintegrates into individual fractions, making this device for producing self-foaming gas-filled foam unsuitable for fire protection of tanks containing oil and petroleum products. Another drawback is that the combustion products of the gas generator are fed exclusively to the bottom of the tank through a conical diffuser, which makes the saturation and mixing processes of the solution protracted.

A method for producing self-foaming gas-filled foam and a device for implementing it are known (patent RU 2678257 C1, IPC A62C 5/02 (2006.01), published on 01/24/2019), adopted as a prototype of the claimed method for producing self-foaming gas-aerosol-filled foam and a device for implementing it.

The method involves bubbling combustion products through a foaming agent solution, saturating the solution with gases in a sealed container, and feeding it to the combustion source, forming self-foaming gas-filled foam on its surface. To create the foaming agent solution, the concentrated foaming agent solution is vigorously mixed with water in the container, and then, after a delay of 3 to 10 seconds, the resulting foaming agent solution is fed to the combustion source. A device for implementing this method is also provided. The essence of the claimed device is that in the device for producing self-foaming gas-filled foam, which includes a sealed container, a gas-generating device made in the form of a set of aerosol generators consisting of two or more generators having separate combustion chambers with gas-inlet pipes, switched on simultaneously, sequentially or in groups in accordance with the required intensity of supply of the foaming agent solution to the combustion source and ensuring the outflow of combustion products of the aerosol generators into the lower part of the container and bubbling of the foaming agent solution with saturation of the solution with fire-extinguishing aerosol, wherein the sealed container is filled with water, and the concentrated foaming agent solution is stored in a separate container on which a gas-generating device is installed, similar to generators mounted on a container with water.

The disadvantage of this technical solution is that the concentrated foaming agent solution is stored in a separate tank outside the main mixing tank and equipped with a separate gas-generating device, which complicates the design and requires more metal. When the gas generator is activated, the concentrated foaming agent begins to flow into a sealed container containing water, which is fed to a single point at the bottom of the tank. Thus, according to the "Great Russian Encyclopedia" (https://old.bigenc.ru/chemistry/text/862201?ysclid=m50urq0326579326574), at a low superficial gas flow rate, when individual bubbles move at velocities close to the free ascent velocity, bubble mode B occurs. Thus, the process of mixing a concentrated foaming solution with water and saturating the solution with the combustion products of the aerosol-forming composition is not pulsed or explosive in nature and is extended over time, which negatively affects the quality of mixing and the response time of the fire extinguishing system. In addition, to create pressure and displace the prepared foaming solution, it is necessary to include additional gas generators in the tanks, which complicates the process of adjusting the operation of the system without an additional algorithm. Due to the above, the method for producing self-foaming gas-filled foam and the device for its implementation are quite complex for implementation and operation as a fire extinguishing system.

The objective of the claimed method for producing self-foaming gas-aerosol-filled foam and the device for implementing it is to improve the fire extinguishing efficiency for fire protection of oil and petroleum product tanks due to the simplicity and speed of its production, namely, separate storage of the foaming agent solution components in a single container, and pulsed, up to 1 s, mixing and saturation of the aerosol-forming composition with combustion products directly throughout the entire volume of the container through a bubbler, and pulsed delivery as a result of the operation of membrane-rupture devices at a given pressure. Thus, according to paragraph G.4 of SP 155.13130.2014 "Oil and Petroleum Product Warehouses. Fire safety requirements""The calculated amount of foaming agent solution in a pulse fire extinguishing system must ensure a specific consumption of fire extinguishing agent (self-foaming gas-aerosol-filled foam) on a horizontal surface (base area) of a tank, regardless of its design, of 12 l × m ^-2 with a supply duration of no more than 40 seconds."

The essence of the claimed method lies in the pulsed, up to 1 s, mixing of a concentrated solution of a foaming agent with water and saturation with combustion products of an aerosol-forming composition through a bubbler upon the operation of a membrane-rupture device at a pressure of 0.8-1.2 MPa. As a result of the use of a membrane-rupture device and a bubbler, at high flow rates, gas jets are formed above the bubbler holes, the destruction of which gives rise to bubbles of various sizes and shapes. The bubbles continuously collide, merge and fragment. Their movement along trajectories that deviate significantly from the vertical ensures liquid circulation in the volume of the entire bubbling layer (Great Russian Encyclopedia (https://old.bigenc.ru/chemistry/text/862201?ysclid=m50urq0326579326574).

The essence of the claimed device is that in the device for producing self-foaming gas-aerosol-filled foam, consisting of a sealed container with water with an operating pressure of 1.5 MPa, a sealed container with a concentrated solution of a foaming agent, one generator with an aerosol-forming composition, a bubbler, two membrane-rupture devices and an outlet pipe, a mechanism for pulsed production of self-foaming gas-aerosol-filled foam is achieved as a result of desorption, due to the operation of the membrane-rupture devices and mixing of the concentrated solution of the foaming agent with water using a bubbler and saturation with gaseous and solid combustion products of the aerosol-forming composition.

Figure 1 shows a device that implements the claimed method for producing self-foaming gas-aerosol-filled foam.

The device consists of a sealed container 1 with an operating pressure of 1.5 MPa, filled with water 2 with a given filling coefficient, a sealed container 3 with a concentrated solution of foaming agent 4. A generator with an aerosol-forming composition 5 and a launch unit 6 are installed on the container 1. A membrane-rupture device 7 is installed between the container 3 and the bubbler 8. An outlet pipe 10 with a membrane-rupture device 9 is installed in the lower part of the container 1. The device is assembled on a frame 11, ensuring the stability of the working position during its operation. Operating principle of the device.

When a signal is sent to the trigger unit 6, the generator with the aerosol-forming composition 5 is activated. The combustion of the aerosol-forming composition results in the formation of gaseous and solid combustion products, which are fed into the container 3 containing the concentrated foaming agent solution 4, creating excess pressure therein. When the excess pressure in the range of 0.8-1.2 MPa is reached in the container 3, the membrane-rupture device 7 is activated and the concentrated foaming agent solution 4 with the dissolved gaseous and solid combustion products of the aerosol-forming composition enters the container 1 containing water 2 in a pulsed manner through the bubbler 8, with mixing occurring directly throughout the entire volume of the container 1 over a period of up to 1 s. As the combustion of the aerosol-forming composition continues, the saturation of the solution with combustion products and the creation of excess pressure continues. When the specified excess pressure parameter is reached, the membrane-rupture device 9 is triggered, and the foaming agent solution with gaseous and solid combustion products dissolved in it is pulsedly supplied from the container through the outlet pipe 10, resulting in the formation of self-foaming gas-aerosol-filled foam as a result of desorption and its subsequent supply to the source of fire.

The technical effect of the claimed method makes it possible to increase the efficiency and speed of obtaining self-foaming gas-aerosol-filled foam as a result of storing a concentrated foaming agent solution in a separate container located inside a container with water and separated by a membrane bursting device, which, when triggered by an increase in pressure to 0.8-1.2 MPa, causes pulsed, up to 1 s, mixing of the solution components through a bubbler with saturation of the foaming agent solution with gaseous and solid combustion products of the aerosol-forming composition, as well as the use of one common generator with an aerosol-forming composition, and then, during the desorption process, when the second membrane bursting device on the outlet pipe is opened, pulsed production of self-foaming gas-aerosol-filled foam with a flow rate and intensity that meet the requirements of the regulatory document (clause G.4 of SP 155.13130.2014 “Oil and oil product warehouses. Fire safety requirements "The calculated amount of foaming agent solution in a pulse fire extinguishing system must ensure a specific consumption of fire extinguishing agent (self-foaming gas-aerosol-filled foam) on a horizontal surface (base area) of a tank, regardless of its design, of 12 l *× m ^-2 with a supply duration of no more than 40 seconds."

The technical effectiveness of the claimed device is due to its use in producing self-foaming gas-aerosol-filled foam. The use of a single generator and aerosol-forming composition simplifies the design and facilitates maintenance.

To confirm the effectiveness of the claimed method for producing self-foaming gas-aerosol-filled foam using the device for its implementation, full-scale tests were conducted, which showed the following:

- the required by the regulatory document SP 155.13130.2014 "Oil and Petroleum Product Warehouses. Fire Safety Requirements" clause G.4 "The calculated amount of foam concentrate solution in the pulse fire extinguishing system must ensure a specific consumption rate of the extinguishing agent (self-foaming gas-aerosol-filled foam) on the horizontal surface (base area) of the tank, regardless of its design, of 12 l × m-2 with a delivery duration of no more than 40 seconds" intensity with this method and application of the proposed device is not only achieved, but also significantly exceeds the minimum requirements. The specific consumption rate of the extinguishing agent (self-foaming gas-aerosol-filled foam) on the horizontal surface of the tank was 12 l × m ^-2 with a delivery duration of 20 seconds.

- the required response time of automatic fire alarm systems (UIS) in accordance with the regulatory document SP 155.13130.2014 "Oil and petroleum product warehouses. Fire safety requirements", clause G.5 "The response time of automatic fire alarm systems (UIS) should not exceed 60 seconds" was less than 10 s with this method and the use of the proposed device.

- the volume of the remaining fire extinguishing agent solution was 0% (requirement of clause 5.23 of GOST R “Impulse fire extinguishing installations for supplying self-foaming gas-aerosol-filled foam” (at the stage of approval in the State Standard) “no more than 10% of the total volume of water and foaming agent filled into the installation”).

- the foam expansion ratio was 7 (requirement of clause 5.25 of GOST R “Impulse fire extinguishing units for supplying self-foaming gas-aerosol-filled foam” (currently being approved by the State Standard) “the unit must ensure the supply of self-foaming gas-aerosol-filled foam of low expansion ratio, not less than 4”).

The result is high fire extinguishing efficiency due to pulsed, instantaneous, up to 1 second, mixing of a concentrated foaming agent solution with water and saturation of the finished foaming agent solution with combustion products of the aerosol-forming composition using a single common aerosol-forming generator.

Claims (2)

1. A method for producing self-foaming gas-aerosol-filled foam, including pulsed mixing of a concentrated foaming agent solution with water simultaneously in the entire volume of a container and saturation of the finished foaming agent solution through a bubbler with gaseous and solid combustion products of the aerosol-forming composition as a result of accumulation of excess pressure, actuation of membrane-rupture devices and production of self-foaming gas-aerosol-filled foam at the outlet pipe, characterized in that the method is carried out using a device for producing self-foaming gas-aerosol-filled foam, in which the concentrated foaming agent solution is stored in a separate sealed container inside a sealed container with water, and the finished foaming agent solution is produced pulsed for up to 1 s by mixing the concentrated foaming agent solution with water as a result of actuation of the first membrane-rupture device when the pressure increases to 0.8-1.2 MPa, and then as a result of the increase in pressure and actuation The second membrane-rupture device on the outlet pipe of the tank, due to the pressure difference, produces self-foaming gas-aerosol-filled foam as a result of desorption. 2. A device for producing self-foaming gas-aerosol-filled foam, consisting of a sealed container with water with an operating pressure of 1.5 MPa, a sealed container with a concentrated solution of a foaming agent, a generator with an aerosol-forming composition, a bubbler, two membrane-rupture devices and an outlet pipe, characterized in that the concentrated solution of the foaming agent is stored in a separate sealed container inside the sealed container with water, the first membrane-rupture device is located between the bubbler and the sealed container with the concentrated solution of the foaming agent and is designed with the possibility of being triggered when a pressure in the range of 0.8-1.2 MPa is reached as a result of combustion of the aerosol-forming composition of the generator with the aerosol-forming composition, wherein the device for producing self-foaming gas-aerosol-filled foam is designed with the possibility, when the first membrane-rupture device is triggered, of pulsed mixing for up to 1 s through the bubbler of the concentrated solution a foaming agent with water with saturation with gaseous and solid combustion products of an aerosol-forming composition in the entire volume inside a sealed container with water, the second bursting device is located on the outlet pipe and is designed with the possibility of being triggered after the first membrane bursting device is triggered when excess pressure is reached for pulsed delivery through the outlet pipe of a foaming agent solution with gaseous and solid combustion products dissolved in it with the formation of self-foaming gas-aerosol-filled foam as a result of desorption.