RU2681677C1 - Method of fire-fighting protection of open gases and a device for its implementation - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: invention relates to fire fighting equipment and is intended to contain a fire that has arisen in open technological openings, for example, when painting large-sized items or on the stage of an auditorium, using an elastic flame retardant barrier, made, for example, in the form of a descending curtain, made in the form of a multilayer mesh screen. Objective of the invention is to increase the efficiency of fire protection of openings by creating in them pre-fabricated fire blocking barriers. Essence of the proposed method lies in the fact that in the way of fire protection of openings, including closing the opening with several screens, for example two, blocking this opening with a fire blocking barrier by filling the screen cellular structure with non-flammable material hardening in air during a fire to seal the said opening and extinguishing the source fire extinguishing agents available when creating a fireblocking obstacle at the same time, additional filling of the space formed by the screens with non-combustible material, which is carried out in the form of a fast-hardening foam, is carried out simultaneously, moreover, the named space is divided into zones, the size of which is determined depending on the predetermined filling rate of each section with a non-combustible material and the time of hardening of the fast-hardening foam. Essence of the claimed device lies in the fact that in the fire-blocking device for fire protection of openings, containing a multi-layer mesh screen, made, for example, in the form of a two-layer package, and means for filling the cellular structure of the screen with a non-combustible hardening material in case of fire in the air for sealing the said opening, volume formed by the multi-layer screen is divided into sections, and the non-combustible material is made in the form of a quick-hardening foam.

EFFECT: claimed technical solution is easy to use and allows the operation of creating a local fire protection facility in case of an emergency situation to be performed several times with a single fire-blocking device, when human intervention in the ongoing process in these conditions is usually short-lived or almost impossible.

2 cl, 11 dwg

Description

The invention relates to fire fighting equipment and is intended to localize a fire that occurred in open technological openings, for example, when painting large items or on the stage of the auditorium, using an elastic fireproof barrier made, for example, in the form of a falling curtain made in the form of a multilayer mesh screen.

In the event of a fire in the controlled area, the open technological opening is closed with a multilayer mesh screen, and the space formed by the screens is filled with non-combustible material made in the form of quick-hardening foam.

Known devices (M.Ya. Roitman. Fire prevention in construction. M., Stroyizdat, 1978), which consist of the following elements: frame, thermal insulation of the frame, the lifting and lowering mechanism and sealing units.

The disadvantages of these devices include their bulkiness. In large modern theaters, the fire curtain weighs over 25 tons. To place a curtain of a lifting type, it is necessary to have sufficient space above the stage, and for a sliding type, to the side of the stage.

For sealing along the upper edge of the curtain, a metal trough is used, equal in length to the curtain and filled with dry sand, into which the curtain canopy is immersed.

Pairing the curtain with the side rails does not provide proper tightness and does not guarantee that the curtain will jam if it is skewed during lowering. In addition, these shortcomings do not provide a set of measures to protect people in the movement zone of the fire curtain from injury.

However, based on the fact that the total water flow required to create a curtain reaches large values, the use of this method as part of other automatic fire extinguishing installations can create a problem of uninterrupted water supply with an existing water supply system at the facility (E.N. Ivanov, Fire protection of open installations. M., Chemistry, 1986, S. 83-95).

Known anti-smoke fire system, which provides for the creation of a fire non-flammable curtains, cutting off a certain part of the room from the place of fire. At the same time, the curtain is watered on both sides by jets of water discharged from fire hydrants (Japanese Application No. 670991, A62C 2/06 of March 15, 1994).

However, the use of fire hydrants leads to significant water consumption necessary for cooling the curtains, and does not allow for the formation of the most effective continuous film flow for cooling.

Known fencing to limit the spread of fire (Copyright SU No. 860770, A62C 3/02 (2000.01), publ. 09/07/1981), which consists of a tape made of fireproof material wound on a reel and a rack with a weighted base, and one the end of the tape is attached to the stand and the other to the reel. In the upper part of the reel and rack, there are transportation rings connected by an earring, and flags are placed on the upper edge of the tape to visually control the final deployment of the tape.

The fence works as follows.

Near the fire hazardous place, a stand is installed with a base heavier for its stability and frontally in relation to a possible fire source, a tape made of non-combustible material is deployed from the coil. By the number of flags that appear, placed on the upper edge of the tape, determine the degree of deployment of the tape.

The disadvantages of this device include its bulkiness and the inability to install this device in narrow and inconvenient for work openings and compartments

A known method that implements a device for localizing a fire (USSR copyright certificate No. 772555, А62С 3/02, 10.23.1980). The principle of operation of this device is that a vertically flexible non-combustible barrier is installed along the front of the fire propagation, then a seal is formed on the lower part of the barrier using a perforated sleeve by supplying a fire-extinguishing liquid into it and expiration of this liquid under pressure through its perforations. Thus, flame propagation under the barrier is blocked, as well as flame propagation in a vertical plane along its entire height and length.

The disadvantage of this device is that it is stationary, it interferes with unimpeded work in an open opening. In addition, the design of the seal does not exclude the possibility of the passage of combustion products (fumes and gases) through the upper and side edges of the flexible fence.

A known method of fire protection of open openings and a device for its implementation (Patent RU No. 2330699, A62C 2/10 (2000.01), A62C 3/02 (2000.01), publ. 10.08.2008).

In this technical solution, to cover the open technological opening, the screen is divided into two panels, with the panel facing the evacuation zone, dust and gas protection of the open opening and sealing the gap between this screen panel and the frame, and the panel facing the fire zone is produced fire protection of an open doorway. Moreover, after the evacuation of people from the danger zone and the creation of dust and gas protection of an open doorway, an inert gas is supplied to the space formed by the said panels.

In the device that implements the method of fire protection of open openings, the load mounted on the front of the protective screen is made in the form of a movable system of drums dividing the screen when it is lowered into two panels. After evacuating people from the danger zone and completely blocking the open technological aperture with the named panels, they form a space between themselves. After creating a seal of the gap between the screen panel facing the evacuation zone and the frame, an inert gas, such as carbon dioxide, is supplied to this space. The screen panel facing the evacuation zone is made of dust and gas impermeable material, and the other screen panel facing the fire zone is made of fireproof material.

However, this device has a complex and bulky design.

In the claimed technical solution, the created screen has a significantly lower mass. So, for example, foamed silica gel (Patent RU No. 2590379, C01B 33/16 (2006.01), publ. 07/10/2016) in a dehydrated state has a bulk density of 0.05-0.1 g / cm ³ and retains at least 95% volumetric form when heated to a temperature of 1000 ° C for at least 40 minutes.

From the above example it follows that the non-combustible material used in the claimed technical solution, made in the form of quick-hardening foam, has significantly better thermophysical especially weight characteristics compared to woven non-combustible materials.

A known method of extinguishing fires and fire protection of objects in case of fire (Patent RU No. 2246976, A62C 3/06 (2000.01), publ. 02.27.2005), adopted for the prototype of the claimed technical solution.

The essence of this method lies in the fact that the reservoirs reduce the flow of vapors, gases and heat fluxes into the combustion zone using nets or mesh bags that are treated with expandable fire-retardant paints and the mesh or mesh bags are placed inside the liquid.

In case of fire, the distance between the liquid and the mesh or mesh bags is established by changing the liquid level or the position of the mesh or mesh bags relative to the liquid level, taking into account the type of fire-retardant paint (adhesion, foaming rate), the geometric dimensions of the mesh or mesh package (wire diameter, mesh size ), the distance between the liquid and the net or net bag, the type of liquid.

A flame treated by a foaming fire retardant paint begins to act on the net. The mesh material is heated, foaming occurs, the foam coke overlaps the mesh cells, and the mesh becomes impermeable to vapors, gases and heat fluxes, and combustion stops.

However, the application of this technical solution will not be effective in extinguishing a fire for the following reasons.

1. It is known (konstanta30.wordpress.com / fire protection of metal structures / Building Blog) that modern flame retardants are applied to the protected surface with a layer up to 2 mm thick. Under the influence of high temperatures increase in volume up to 70 times and have fire retardant efficiency up to 90 minutes. As practice shows, the application of fire-retardant intumescent paints with a layer of more than 2 mm is impractical, because with a thickness of more than 2 mm the layer of fire-retardant paint warms up and swells unevenly. This leads to heterogeneity of the resulting protective layer, a decrease in its strength and leads to the fact that the fire retardant layer is crumbled.

For these reasons, the size of each mesh cell should be no more than 4 by 4 mm in order to ensure that the foam area overlaps the entire area of this mesh cell.

2. It is known (EN Ivanov. Fire protection of open technological installations. - 2nd ed., Revised and supplemented. - M .: Chemistry, 1986, p. 20) that in the event of an outflow of gases or flammable liquids it is advisable to block objects adjacent to the emergency apparatus. In this case, the heat exchange between the flame torch and the process equipment is of significant importance.

Large open fires are characterized by diffusive combustion of volatile gases released during combustion in a gas-air turbulent flow. In this case, the burning rate, and, consequently, most of the characteristics of a fire, depends on the process of absorption of air into the mixing, heating, and combustion zones. Due to the large difference in temperatures and densities in the combustion zone and the environment, significant vertical velocities of the movement of hot gases are created, which lead to discharge near the convective column, where air rushes from the surrounding atmosphere.

It is generally accepted (EN Ivanov. Fire protection of open technological installations. - 2nd ed., Revised and supplemented. - M.: Chemistry, 1986, p. 23) that the average velocity profiles, temperature and density are selected for all sections of the convective jet column; air intake into the combustion zone (in the absence of wind) is proportional to the average speed (on the axis of the column of the same height).

Studies show that in the convective part of the jet there is an uneven temperature distribution, both along the height of the jet and in its cross section. The highest temperature is observed on the axis of the jet and the lowest - on its boundary. The temperature decreases with distance from the burning site.

In the work (EN Ivanov. Fire protection of open technological installations. - 2nd ed., Revised and supplemented. - M .: Chemistry, 1986, p. 21) it is noted that the turbulent convective jet consists of three zones, between which there is no abrupt transition.

Moreover, zone I represents the diffusion part of the flame with the highest temperature and radiation.

For example, in this work, the flame temperature of crude oil, diesel fuel, and tractor kerosene, which is 1373 ° K, is given.

It is known (Effective intumescent paints for fire protection of metal structures, http://ngdelo.ru/files/old_ngdelo/2012/3/ngdelo-3-2012-p174-178.pdf) that intumescent paints became popular in many countries fire-retardant paints, which are applied in a thin layer on the surface of structures and in the process of operation, perform the functions of a decorative and finishing material. During fire exposure, foam coke is formed, having a coating volume many times larger than the initial one and preventing the metal from heating to a temperature at which the structure loses its bearing capacity. With prolonged fire exposure, the foam coke gradually burns out and after a certain time, usually not exceeding 1 h, mechanically breaks down and flakes off the surface.

It follows that created using this method (Patent RU No. 2246976, A62C 3/06 (2000.01), publ. 02.27.2005), the fire-blocking barrier will be insufficient in case of fire, since the fire resistance of the foamed fire-retardant layer from the foam coke will be much lower than the average duration of the fire in tanks.

Therefore, in the claimed technical solution, when creating a fire-retardant barrier, the inventors propose using quick-hardening foam, which according to the data in (Scientists propose to extinguish fires with quick-hardening foam. News. 0-1.ru.html), can withstand temperatures up to 1000 ° C for a long time without significant self destruction.

The objective of the invention is to increase the effectiveness of fire protection of open apertures by creating rapidly erected fire-blocking barriers in them.

The essence of the proposed method lies in the fact that in the method of fire protection of open openings, which includes closing the opening with several screens, for example, two, closing this opening with a fire barrier by filling the cellular structure of the screen with a non-combustible hardening material in air in case of fire to seal the said opening, and extinguishing the fire with available extinguishing media, while creating a fire-retardant barrier, additional filling of the formed screen is simultaneously carried out space, non-combustible material, which is performed in the form of quick-hardening foam, and the above-mentioned space is divided into zones, the size of which is determined depending on the specified filling speed of each section of non-combustible material and the curing time of the quick-hardening foam.

The essence of the claimed device lies in the fact that in a fire-retarding device for fire protection of open openings containing a multilayer mesh screen, made, for example, in the form of a two-layer package, and means for filling the cellular structure of the screen with a non-combustible hardening material in case of fire in air for sealing the said opening, this volume formed by a multilayer mesh screen is divided into sections, and non-combustible material is made in the form of quick-hardening foam.

The technical effect realized by the claimed method is determined by the following.

The additional filling of the space formed by the screens with non-combustible material makes it possible to create a quickly-assembled fire-blocking barrier of non-combustible material made in the form of quick-hardening foam with increased heat resistance and gas impermeability (Patent RU No. 2590379, C01B 33/16 (2006.01), publ. July 10, 2016, Application RU for the invention No. 2016125510, IPC A62C 3/02 (2006.01), A62D 1/02 (2006.01), publ. 12/28/2017).

The breakdown of the space formed by the screens into zones is carried out in the claimed technical solution for the following reasons.

First, it was previously established (AN Baratov, EN Ivanov. Fire extinguishing at the enterprises of the chemical and oil refining industries. 2nd revised edition. M., Chemistry, 1979, p. 73), which increases the viscosity its foam resistance increases, but the spreadability on a burning surface worsens.

According to the authors of the invention, quick-hardening foam is a substance with a variable viscosity, the value of which increases rapidly as the protective layer of the foamed heat-insulating substance hardens. This is confirmed by the data presented in the work (Testing of new fire extinguishing chemical compositions and development of recommendations for their use: report on research (conclusion) / FBU "SPbNIIILH"; head. Gutsev ND; execution: Artsybashev ES, Mikhailova N.V., Korchunova I.Yu. - St. Petersburg, 2014 .-- 254 p. - Bibliography: p. 112-120. - No. GR 01201255954. - Inv. No. 215022440055, 11).

Secondly, the rate of deceleration of the flow along the surface by the cellular structure of the screen depends on the number of cells, the thickness of the wire from which the mesh is woven, the adhesive properties of quick-hardening foam and other factors characterizing this process.

In this connection, when filling large volumes of space formed by screens with non-combustible material, areas with an uneven layer of the created coating or a section in which there is no layer of quick-hardening foam can be observed.

Therefore, for these reasons, the size of the zone is determined depending on the specified filling rate of each section with non-combustible material and the curing time of the quick-hardening foam.

The technical effect realized by the claimed device is determined by the following.

The breakdown of the volume formed by the multilayer mesh screen into sections allows you to ultimately create a solid prefabricated barrier from separate parts. Due to the fact that quick-hardening foam has a high adhesive ability, these flows "merge" at the joints of the mesh structure of each section and form a single whole.

The execution of non-combustible material in the form of quick-hardening foam makes it possible to simplify the process of creating a quickly erected fire-blocking barrier from non-combustible material, and to erect the barrier itself as soon as possible.

According to the authors of the invention, the characteristics given in the claims are necessary and sufficient to achieve the specified technical result, that is, they are essential.

Thus, the distinguishing features of the proposed technical solution are new and meet the condition of patentability "novelty."

When determining the conformity of the distinguishing features of the present invention with the patentability condition “inventive step”, the prior art and, in particular, known methods and devices relating to means of containing fire (fire retardation) were analyzed.

A known method of fire protection of open apertures and a device for its implementation (Patent RU No. 2244578, A62C 2/10 (2000.01), A62C 3/02 (2000.01), publ. 20.01.2005), including closing in case of fire an open opening with a protective screen mounted on the frame, creating a seal of the gap between the screen and the frame to prevent the ingress of combustion products from the fire after the protective screen completely covers the open opening.

Prior to the installation of the device for localizing the fire, the boundary of the upper level of operation is determined before the fire is detected, and after the detection of the fire, the means for suppressing the kinetic energy arising from the movement of the screen are installed above the specified border, then the protective screen is moved with the acceleration of gravity and after the said screen comes into force with the means of quenching the kinetic energy, when they are moved together, they completely quench the kinetic energy acquired by the screen and stop A shield of the protective screen is at the boundary of the upper level of working actions, and further movement of the screen is carried out with a delay determined by the formula:

T = t ₁ + t ₂ + t ₃ ,

where T is the delay time for further screen movement;

t ₁ - time of perception by a person of a fire warning signal;

t ₂ - the time a person makes a decision to evacuate from the danger zone;

t ₃ - time of evacuation of a person from the farthest point of the danger zone,

then carry out further slow movement of the screen to the lower level of working actions, for example to the floor.

However, this device has a complex and bulky design.

It is known (http://stroy-king.ru/vse-ob-ognestojkix-montazhnyx-penax.html) that fire-resistant foam is used for fireproof insulation. This is a one-component polyurethane foam sealant, completely ready for use and polymerized under the influence of moisture in the atmosphere.

Special substances introduced into the recipe provide an excellent acoustic and thermal effect. Such an insulating layer does not allow smoke and gases to pass through.

Foam can withstand open fire 60, 120, 180, 230, 240 minutes (depending on version). The higher the requirements for fire safety at the premises, the higher should be the indicators of fire resistance.

However, the foam completely hardens only after a day. For this reason, the use of synthetic foam as a non-combustible material to create a pre-fabricated fireproof barrier in the present invention is impossible.

There is a method of conducting emergency emergency repairs on pipelines with oil and oil products (Patent RU No. 1743614, A62C 3/00, publ. 30.06.1992).

Ensuring the safety conditions for hot work, reducing the duration and reducing the complexity of preparatory operations is achieved by driving plugs from quick-hardening foam at the beginning and end of the damaged section, filling the volume of the pipeline between the plugs and the technological foundation pit with air-mechanical foam, and also controlling gas contamination at the work site. Quick-hardening foam is used as plugs, and the pipeline between the plugs and the technological foundation pit are filled with air-mechanical foam. This method is intended to eliminate emergency situations on pipelines with oil and oil products in preparing them for hot work to prevent an explosion and the development of a fire.

However, when creating a plug in the pipeline, before it hardens on the local section of the pipeline, it spreads along the latter, since the foam does not have any obstacles, for example, a multilayer mesh barrier, provided for this purpose in the claimed technical solution.

A known method of extinguishing a flame of combustible gases and a device for delaying fire and the free passage of combustible gases (Patent RU No. 2552901, A62C 4/00, publ. 06/20/2015).

The method includes creating an additional layer of a granular body from a microencapsulated extinguishing agent in the flame retardant element in front of the granular body layer from the side of the flame of burning gases, the shell of which is thermally destroyed by the flame of combustible gases, and the extinguishing agent is transferred from the liquid state to a gaseous state, leading to inhibition of the rate of chemical reactions of a flame of combustible gases, while the flame retardant element in the device for holding fire free passage of combustible gas is moved as a result of weight reduction further layer of granular bodies of microencapsulated extinguishing agent, whereby the launch a governing body locking-starting device and a supply of finely divided extinguishing agent towards the flow of combustible gases.

In the device for holding fire and the free passage of combustible gases, the cartridge is divided into zones, each of which is filled with a granular body, and the zone filled with an additional layer of granular body of a microencapsulated extinguishing agent, made in the form of microcapsules with a fire extinguishing agent, is placed on the side of the flame of burning gases, and the fire-retarding element has a means for moving, while reducing the mass of an additional layer of granular body from a microencapsulated extinguishing agent and is connected to the governing body of the locking and starting device for supplying finely atomized extinguishing agent to the flow of combustible gases, while a fixing grid is mounted in the cassette between the zones filled with various granular bodies.

However, all grids included in the devices are intended only for the separation of granular bodies and their use to create continuous rigid non-combustible barriers using quick-hardening foam is not provided for by this technical solution.

In the work (II Strizhevsky, VF Zakaznov. Industrial fire suppressors. - M .: Chemistry, p. 74), the use of metal grids as fire suppressors is noted. So, for example, metal mesh with a cell diameter less than critical can be used to prevent the spread of combustion (fire).

The same nets can be used to extinguish fires and as heat shields to protect people and equipment from heat. The small diameter of the mesh cells does not give advantages over solid metal screens. The scope of such extinguishing nets is also limited due to the impossibility of implementing the extinguishing mechanism by the sealing method.

Analysis of other technical solutions showed that the known methods and devices do not solve the previously mentioned problems, solved by the claimed method and device.

Based on the foregoing, we can conclude that the claimed technical solution meets the condition of patentability "inventive step", and the invention itself is new.

The implementation of the technical solution can be implemented as follows.

When implementing the proposed technical solution, it is necessary to consider the following well-known information from the prior art.

It was previously established (Abstract on the theme “Development of fire-retardant mesh screens with expandable epoxy coatings and overlapping foam coke cells in a fire”. A. S. Krutolapov. Scientific library of dissertations and abstracts; disserCat http://www.dissercat.com) that Passive fire protection of technological equipment is the most rational and reliable way to both prevent fire and reduce the impact of its dangerous factors. Often passive methods of protection that do not require human intervention in the ongoing process become competitive with active ones and can partially or completely replace them.

One of such methods of passive fire protection of technological equipment of the oil and gas complex is fireproof screens. They are designed to prevent tanning, slowing down or stopping the development of the initial stage of a fire, ensure its localization, reduce the impact of hazardous factors on apparatuses and pipelines (S.V. Sobur. Fire Protection of Building Materials and Structures: Reference Book. - M.: Special Equipment, 2001. p. . 112). At the same time, the application of such measures to improve fire safety is not always justified if fireproof screens are made in a traditional design (walls, partitions, etc.), which can create certain inconveniences, and sometimes increase the fire hazard. Recently, studies have been carried out on the possibility of using grids as screens to protect against thermal effects of a fire (NN Brushlinsky, M.Kh. Usmanov. Combined means of protection against thermal damage. // Fire Safety-97).

One of the most elegant and effective engineering solutions in this area is a metal wire mesh used as fire-prevention screens, which are used very widely and for a long time. So, for example, Davy's nets were used in the mining industry since the end of the 18th century and still have not lost their relevance (II Strizhevsky, VF Zakaznov. Industrial fire suppressors. - M.: Chemistry, p. 261) .

A new direction in the passive fire protection of technological equipment is the use of mesh fragments coated with fire-retardant paints, foaming when heated and completely covering the mesh cells with fire-resistant foamox. Foaming coatings practically do not change the necessary functional properties of the grid elements (visual observation of the controlled process or the protected device, maintaining the general climatic and temperature conditions). However, when exposed to high temperature and flame, the free space of the mesh cells is completely blocked by fire-resistant foam coke, forming a heat-insulating barrier to the spread of combustion. Such structures have a number of valuable advantages, namely, relatively easy installation, if necessary, the possibility of free disclosure, the creation of portable structures and, as a result, low financial costs (NN Brushlinsky, M.Kh. Usmanov. Combined means of protection against thermal damage // Fire safety-97: Materials of the scientific-practical conference.Moscow, November 19, 1997 - M .: MIN MINISTRY of the Ministry of Internal Affairs of Russia, 1997. pp. 114-116; V.R. Malinin, O.A. Khoroshilov. devices for the protection of technological equipment and comm of fire propagation: a training manual. St. Petersburg: St. Petersburg Military Technical University Ministry of Internal Affairs of the Russian Federation, 1997, p. 104. Fire prevention in construction. / B.V. Grushevsky, A.I. Yakovlev, I.N. Krivosheee, etc. / Under the editorship of V.F. Kudalenkin - M .: MVIPTSh of the Ministry of Internal Affairs of the Russian Federation, 1985, p. 454).

An obstacle to the wider implementation of grid fire arresting devices is the almost complete absence of a theoretical and experimental study of this issue.

Thus, the creation of heat shields combining the properties of nets and foaming paints is an actual scientific and practical direction, research in which allows us to expand the scope of their use and increase the effectiveness of passive fire protection equipment for oil and gas processing equipment.

The execution of the heat-insulating substance in the form of quick-hardening foam makes it possible to improve the quality of the obtained airtight coating and create a quick-build fireproof barrier with significant fire resistance.

This is due to the fact that quick-hardening foam in a free state on the surface quickly gains mechanical strength.

The invention is further illustrated by an example of its implementation.

In FIG. 1 shows a General view of the inventive device in standby mode (in plan) at the moment when the multilayer mesh screen is wound on a spool and mounted above an open opening with the possibility of its movement along the walls of the opening; in FIG. 2 presents a General view of the inventive device (in plan) at the time of complete closure of the open opening in the initial stage of fire development in a controlled area; in FIG. 3 shows a General view of the inventive device (in plan) at the time of creating a fire-retarding barrier by filling the space formed by the mesh screens with non-combustible material, made in the form of quick-hardening foam; in FIG. 4 shows a cross-section of the inventive device along AA with a view of the left side rack in standby mode; FIG. 5 shows a cross-section of the inventive device along AA with a view of the left side pillar at the time of complete overlap of the open opening in the initial stage of fire development in the controlled area; in FIG. 6 shows a cross section of the inventive device on BB with a view of the right side rack in standby mode; in FIG. 7 is an enlarged view of a fragment of a mesh screen (in plan) until filling the space formed by the mesh screens with quick-hardening foam; in FIG. 8 is an enlarged view of a fragment II of the mesh screen (in plan) after filling with the quick-hardening foam of the space formed by the mesh screens; in FIG. 9 is a cross-sectional view of the mesh screen along B-B (until the quick-hardening foam fills the space formed by the mesh screens); in FIG. 10 is a cross-sectional view of the mesh screen along G-D (after filling with the quick-hardening foam of the space formed by the mesh screens); in FIG. 11 is a cross-sectional view of the mesh screen along the DD at the installation site of the flexible nozzles of the quickly erected collector at the time of the start of feeding the solution with quick-hardening foam into the space formed by the mesh screens.

Flame retardant device (Fig. 1) consists of a frame 1 mounted above an open opening 2. The frame 1 has side racks 3 and 4, in the upper part of which a drum 5 is mounted above an open opening 2. In standby mode, a multilayer mesh screen 6 is wound made, for example, in the form of a two-layer package. In the presented layout solution of the claimed device, the screen 6 consists of two metal grids 7 and 8 (Fig. 9, Fig. 10 and Fig. 11).

The means of moving the screen 6 is made in the form of an electric drive 9 and a brake device 10, which are mounted on an arm 11 mounted on a rack 4.

A base 12 is mounted on the front of the screen 6, at the ends of which axes 13 and 14 are made, which are capable of axial movement in the grooves 15 (Fig. 4, Fig. 5) and 16 (Fig. 6) of the respective struts 3 and 4.

A U-shaped clamp 17 is installed along the contour of the open opening 2, which is connected with the help of swinging elements 18, 19, 20, 21, 22, and 23 to the corresponding drives 24, 25, 26, 27, 28, and 29. Moreover, until the quick hardens completely hardens foam in the space formed by the mesh screen 6, the clamp 17 provides free movement of the latter.

Under the drum 5 with the wound screen 6, a roller 31 is installed on the axis 30 (Fig. 4, Fig. 5 and Fig. 6), which guides the screen 6 along the frame 1 as it unwinds from the drum. Moreover, the roller 31 has the possibility of axial rotation.

An elastic pad 32 is mounted on the front of the base 12.

The mesh screen 6 is made multilayer, for example, in the presented layout solution of the inventive device, as noted earlier, in the form of a two-layer package.

The space formed by the multilayer mesh screen 6 is divided into zones, the size of which is determined depending on the specified filling speed of each section with non-combustible material and the curing time of the quick-hardening foam.

The volume formed by the multilayer mesh screen 6 (Fig. 7, enlarged view I) is divided into sections 33, 34, 35, 36, 37, and 38 (Fig. 2 and Fig. 3). In the presented layout solution, the named volume is divided into six sections.

Sections 33, 34, 35, 36, 37 and 38 of the screen 6 are designed to fill the entire volume with non-combustible material 39 (Fig. 10), made in the form of quick-hardening foam (after deploying the mesh screen in case of fire). Moreover, the time of complete filling of the volume of each section with quick-hardening foam depends on its feed rate and fluidity and the hardening time of the quick-hardening foam.

It was previously established (Application RU for invention No. 2016125510, IPC А62С 3/02 (2006.01), A62D 1/02 (2006.01), publ. 12/28/2017) that the curing time of the foam mainly depends on the amount of acid used in the creation of quick-hardening foam hardener.

It is obvious that if the dimensions of the zone are significant, then as the volume of each section is filled with quick-hardening foam, this process can enter the stage of solidification. As a result, when creating a fire-retarding barrier, the entire volume of the section will not be filled with non-combustible material 39, sections with an uneven layer of the named barrier or with the absence of the latter will be observed.

The means for supplying non-combustible material 39 (Fig. 3, Fig. 10), hardening in case of fire, is made in the form of a quickly erected collector 40, each flexible pipe 41, 42, 43, 44, 45 and 46 of which are mounted on one side 47 of the multilayer mesh screen 6 on the surface 48 of the corresponding section.

The operation of the claimed device is controlled by a block 49, which is controlled automatically or manually by trained personnel in communications 50, 51, the interaction of the electric drive 9 and the brake device 10, drives 24, 25, 26, 27, 28 and 29.

The inventive method is implemented as follows.

In the event of a fire that occurred in an open technological aperture 2, for example, when painting large items or on the stage of the auditorium, the electric drive 9 is automatically started using block 49. Due to the fact that the multilayer mesh screen 6 is a lightweight construction in the claimed technical solution, compared with the screen presented, for example, in the method of fire protection of open openings and a device for localizing a fire (Patent RU No. 2244578, A62C 2/10 (2000.01), A62C 3/02 (2000.01), publ. 20.01.2005), cf. GUSTs clearing kinetic energy that occurs when you move the screen, is not provided. Moreover, the fire-retarding device for fire protection of open apertures, which implements a method of fire protection of open apertures, has one mode of screen movement 6.

For this reason, the screen moves at a constant speed until the open technological opening 2 is completely blocked in the initial stage of fire development in the controlled area. If necessary, the movement of the screen 6 is stopped, and after eliminating the reasons that impede the movement of the named screen, the latter continues its movement along the intended path.

After complete closure of the open technological opening 2 (Fig. 2) on the surface 48 of one side of the side 47 of the multilayer mesh screen 6 of the corresponding section, a quickly erected collector 40 is mounted. accessible place of the hole 52 (Fig. 11), in which they mount the corresponding flexible pipe 41, 42, 43, 44, 45 and 46 /

Then, the volume formed by the multilayer mesh screen of each section 33, 34, 35, 36, 37 and 38 is filled with non-combustible material 39 made in the form of a ready-made quick-hardening foam solution (Fig. 3 and Fig. 11).

Moreover, the filling boundary 53, 54, 55, 56, 57 and 58 in each section 33, 34, 35, 36, 37 and 38 is constantly changing as it is filled with non-combustible material 39.

After the hardening of the quick-hardening foam, the collector 40 and the corresponding flexible pipes 41, 42, 43, 44,45 and 46 are dismantled.

Thus, an open barrier 2 creates a fire-blocking barrier in the space formed by metal sets 7 and 8 (Fig. 10). Quick-hardening foam is a non-combustible substance and an excellent heat insulator. It has high fire resistance, good adhesive ability, due to which it adheres to the surface of the cellular structure of the grids 7 and 8).

The created fire-blocking barrier is capable of a long time to localize the fire that arose in open technological openings.

After extinguishing the fire, the multilayer mesh screen 6 is cut (for ease of dismantling) into parts and removed from the fire blocking device.

Perform a routine inspection of the claimed device, replace the failed parts and mechanisms, install a new multilayer mesh screen 6.

The device after commissioning is ready for operation.

Industrial applicability of the claimed technical solution is as follows.

The proposed fire-blocking device relates to prefabricated structures made of non-combustible material, and the barrier itself can be erected as soon as possible.

Numerous compositions of quick-hardening foam are currently known (Patent RU No. 2590379, C01B 33/16 (2006.01), publ. 07/10/2016; Patent RU No. 2645542, A62C 3/02 (2006.01), publ. 02.21.2018 and so on ), which can:

- successfully upgrade the existing methods of passive fire protection of technological equipment (Abstract on the topic "Development of fire-retardant mesh screens with expandable epoxy coatings and overlapping foam coke cells in a fire." A. Krutolapov. Scientific library of dissertations and abstracts disserCat http: // www. dissercat.com);

- significantly increase the fire resistance of the foamed fire-retardant layer during the construction of a quick-erected barrier (Scientists propose to extinguish fires with quick-hardening foam. News. 0-1.ru.html).

The claimed technical solution is simple to operate and allows repeatedly to perform one local fire protection device to create local protection of the object from fire in case of emergency, when human intervention in the process under these conditions, as a rule, is short-term or practically impossible.

Claims (2)

1. A method of fire protection of open apertures, including closing the aperture with a multilayer mesh screen, for example, a two-layer one, blocking this aperture with a fire-retardant barrier by filling the cellular structure of the screen with a non-combustible hardening material in air during fire in order to seal the said aperture, characterized in that when creating a fire-retardant barrier at the same time, additional filling of the space formed by the screens with non-combustible material is carried out, which is performed in the form of rapid rdeyuschey foam, wherein said space is divided into zones, the size of which is determined according to a predetermined speed filling each section of non-combustible material and the solidification time fast-hardening foam. 2. Fire-retardant device for fire protection of open apertures, comprising a multilayer mesh screen, made, for example, in the form of a two-layer package, means for expanding the mesh screen in case of fire, means for supplying a non-combustible hardening material in case of fire with a fire to seal the said opening, characterized in that that the volume formed by the multilayer mesh screen is divided into sections, each of which, after expanding the mesh screen in a fire, is filled with non-combustible material, are made m in the form of quick-hardening foam, and the means for supplying a non-combustible hardening material during a fire is made in the form of a collector, each flexible pipe of which is mounted on one side of a multilayer mesh screen on the surface of the corresponding section.

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