RU2515460C2 - Method and device for fire fighting localised in volume and/or area in fire hazardous zones of buildings and plants - Google Patents

Abstract

FIELD: fire-fighting equipment.SUBSTANCE: invention relates to a method and device for fire fighting localised in volume and/or area using fire extinguishers in fire hazardous zones of buildings and plants. The invention is based on the object of improving the structural units so that the thermal load in case of fire could not spread to other zones and thus escape routes, openings in the walls and the left technical means such as control means, loaders, etc., with additional minimising of consumption of fire-extinguishing agent and harm reduction in the event of fire while simultaneous improving economical efficiency are maximally protected against the effects of impact of fire-extinguishing agent, and the constructive compensation between the structure and the plant for extinguishing fire is simultaneously achieved. This object is achieved in that around the fire source and/or in fire hazardous zones at least one wall of the fire-extinguishing agent is created of spray mist to prevent the extension of thermal load to other zones along at least one being controlled by means of detecting vertical and/or horizontal plane of sputtering extending between the supports related to fire source, respectively, the fire hazardous zone, and/or simultaneously at least one additional wall of fire-extinguishing agent of spray mist for protection and cooling the escape routes, approach roads, openings in fire walls and technical means inside the building along the spraying plane passing between relating to them supports conducting fire-extinguishing agent..EFFECT: improvement of structural plants.38 cl, 11 dwg

Description

The invention relates to a method for localizing the volume and / or area of fire fighting using fire extinguishing agents in fire hazardous areas of buildings and installations, in which the fire extinguishing agent is supplied from a piping system horizontally located in the building with branches and shutoff valves to the vertical hollow supports of the building from the valve section extinguishing agent and in case of fire, finely spray or spray under pressure in a certain amount and with a specific duration using fire throwing devices of extinguishing agents, in this case, the shut-off valves, after detecting a fire source, are opened by means of detection means for unlocking the extinguishing agent, an initiation signal is generated, and at the same time, an alarm is issued using the central control point, at least one fire warning is sent to the relief site, and an extinguishing means, and also turn off electrical and fire hazardous installations.

In addition, the invention relates to a device for implementing the above method according to the restrictive part of paragraph 20 of the claims.

From DE 102006024688 B3, a method is known for fire fighting localized in volume and / or area using fire extinguishing agents in fire hazardous areas of buildings and installations, in which fire extinguishing agents or fire extinguishing means are kept ready, they are fed to a fixed-mounted building passing through the fire hazard zone a piping system with branches and shut-off valves from the water intake section and in case of fire using spray nozzles is finely sprayed or sprayed under pressure in the calculated quantity and calculated at the same time, while the shut-off valves are opened after a fire is detected using detection means to open the extinguishing agent, and at the same time, an alarm is issued using the central control point, at least one fire message is sent to the relief site, the extinguishing agent is turned on, and electrical and fire-promoting installations, while the fire hazard zones are overlapped by control zones, and they control the autonomous control units using a logical th matrix for fire fighting by dispensing extinguishing agent in accordance with the progress of the fire.

This known method is carried out in such a way that fire hazard zones are divided into separate volume and / or surface elements, volume and / or surface elements are combined into separate control zones with autonomous control units separately coordinated with these zones, and in the control zones they are formed by supplying and distributing a fire extinguishing spray zone means, detect and locate the fire inside the control zones by responding to changes in temperature and / or pressure, coverage which controls all volumetric and / or surface elements of the control zone on at least one surface of the detection and initiation means, which transfers the temperature and / or pressure change to the corresponding control unit, the control zones that surround the fire zone are determined, while blocking the corresponding control units which convert the changes in temperature and pressure into a control value for opening the supply of the extinguishing agent to the fire zone, and depending on the course of the change is set th change of pressure and temperature control units are activated, which surround the fire zone.

Although this method makes it possible to supply a finely dispersed extinguishing agent in a localized volume at the scene of a fire with a high degree of coverage of the corresponding room, evacuation routes, openings in the walls for passage, and existing ones are not included in the zones surrounding the source of fire technical means, so that, on the one hand, the amount of extinguishing agent given is not optimally matched to the actual need and, on the other hand, , damage to goods, respectively, technical means, such as forklifts or the like, with a fire extinguishing agent, is not excluded.

From DE 2457061 C3 a multi-tier storage device with vertical supports and horizontal beams is known, of which at least the supporting vertical supports are made in the form of hollow steel profiles filled with water, which are connected to a water supply pipe, and also to a water discharge pipe, of which one is suitable above and the other below, and there are means for creating a flowing stream of water through the vertical supports in case of fire.

In the event of a fire, the horizontal water-conducting beams are equipped with sprinklers, which, when triggered due to an increase in temperature, open and distribute the supplied water down directly to the rack. The issuance of the extinguishing agent is not consistent with the course of the fire and is carried out in such quantities that damage to the stored goods and technical equipment is not excluded.

This prior art makes the fire extinguishing installation directly an integral part of the rack installation, which is therefore more compact, more material-intensive, more difficult to install and has functional problems in controlling the extinguishing agent, such as tightness, corrosion sensitivity, ventilation, clogging of conductive water pipelines etc. Therefore, this prior art has not received to date the spread in the technique of multi-tier storage.

In addition, this known solution does not contribute to increased fire resistance of the building surrounding the multi-tier storage facility.

In addition, from DE 3021335 A1, a fire protection system for a building with sprinklers is known, which are activated at a predetermined temperature and / or smoke formation and are located on at least one supply medium for extinguishing a fire pipeline. The sprinkler-bearing conduit is connected to at least one aperture-provided duct to form a statically supporting structural member, for example, for a roof or ceiling.

This prior art device also uses sprinklers with all their drawbacks of uncontrolled water supply after opening to extinguish a fire, while the supporting pipeline serves to support the roof or ceiling. The vertical supports of the building do not conduct the environment and are not protected from heating during a fire.

From DE 9301963 U1 is also known a supporting structure with an element of the supporting structure, which has a hollow profile, in the hollow space of which fire extinguishing means is located, while the hollow space of the supporting structure element is hermetically closed, the hollow space is at least partially filled with water in the liquid state and on the element The supporting structure is provided with at least one steam release valve.

In this known solution, according to the state of the art, it is especially open, i.e. In fire hazardous areas, steam release valves are located with rotary nozzles for steam, which in the event of a fire release steam resulting from overheating of the extinguishing medium in the hollow space of the carrier element and direct it to the supporting structure. However, a prerequisite for this is the fire of the entire building, which is rather unbelievable, since the fire always comes from limited places. In addition, this solution is not suitable for the effective protection of those stored in a building, for example, on shelves, products, goods or the like. from emerging fires.

Another well-known solution provides a supporting structure that meets the requirements of fire protection, which has water outlet devices and connecting pipelines to each other and to the central water supply device, while the water discharge devices and the central water supply device are actuated using a fire device alarm. Spray nozzles are used as water discharge devices, and they are located and made along at least part of the supporting structure so that water leaves them in the form of finely distributed droplets or aerosol, the edge zones of the exit cones of adjacent spray nozzles intersect each other in the case of parts of the supporting structure lying in the radius of their action envelop the fog.

In this prior art solution, a fire extinguishing agent is also produced uncontrollably and independently of the progress of the fire. Evacuation routes, openings in walls and technical equipment are exposed to the extinguishing agent throughout the surface. The consumption of the extinguishing agent is accordingly large, and the possibility of preventing the harm caused by the extinguishing agent is not ensured.

At the same time, the basis of the invention is the task of improving the method and devices of the type indicated at the beginning for building installations so that the thermal load in the event of a fire cannot spread to other areas, and evacuation routes, access roads, openings in walls and abandoned technical means , such as operating equipment, loaders, etc., were protected as much as possible from the effects of the extinguishing agent, while the consumption of the extinguishing agent was further minimized and the harm was reduced in case of ara while increasing efficiency, and simultaneously is achieved Engineering compensation between the structure and installation for fire fighting.

This problem is solved using the method with the characteristics of paragraph 1 and a device with the characteristics of paragraph 20 of the claims.

Preferred embodiments of the solution according to the invention are given in the dependent claims.

The solution according to the invention proceeds from the idea of a functional combination of fire detection and / or fire extinguishing, and / or localization of the fire, and / or fire control of individual industrial installations, for example, multi-storey warehouses, with the fire concept of the structure surrounding the installation and the creation of fire walls from the extinguishing agent around fire hazard zones and / or in fire hazard zones.

This is achieved by the fact that around the fire hazard zones and / or in these zones, such as, for example, the zones of a multi-storey warehouse, a wall of fire extinguishing agent is created from spray mist to prevent the spread of the fire to zones adjacent to the fire center along the supports supported between the conductive fire extinguishing means using means of detecting the spray plane, while inside the fenced off fire so you can use known per se, dynamically coordinated with the course of the fire methods fire extinguishing, such as, for example, those specified in DE 102006024688 B3. At least one additional dense fire extinguishing agent wall from spray mist is created to protect evacuation routes, access roads, openings in fire walls and around technological devices inside the building along the vertical conductive supports of the extinguishing agent, so that the spread of thermal load from the source is reliably excluded fires in other zones.

In this case, the vertical supports of the building are located so that the supports carrying the extinguishing medium around and / or in fire hazardous areas, or along the escape routes, access roads, fire walls, or technological devices, occupy such a position that the supports and the extinguishing device discharge devices located on the supports can form spray planes controlled by means of detection with each other, in which in case of fire, dense and homogeneous fire walls can be created between the respective supports detergent from spray mist.

This is due to the extremely great advantage of the targeted use of the extinguishing agent in the local volume, due to which it is possible, for example, to keep escape routes, access roads, etc., free from the extinguishing agent. This leads to significant savings of the extinguishing agent and a significant reduction in damage through the use of the extinguishing agent, while simultaneously increasing the fire resistance of the building and technical installations.

A significant advantage is the ability to abandon fixed fire walls, which significantly reduces the cost of construction. At the same time, it is also possible to carry out the construction using lightweight structures due to the many vertical supports used.

The device according to the invention is characterized in that the vertical hollow supports around and / or in at least one fire section form vertical and / or horizontal spray planes, while at least the detection means and the control unit are designed to turn on and off the fire extinguishing means releasing devices spray planes, and that all spray planes and control units have a common logical matrix to simultaneously initiate fencing of the fire and, respectively, of the fire hazard zone and for the protection and cooling of escape routes, openings in fire walls and technological devices using fire extinguishing agent walls.

This provides, for example, the possibility of fencing off the source of fire, respectively, of the fire hazard zone and the areas surrounding the source of fire using a closed ring of fire extinguishing agent walls between supports from adjacent areas of the structure, so that the thermal load from the source of fire cannot penetrate into adjacent areas.

Other advantages and details follow from the description below with reference to the accompanying drawings.

The following is a more detailed explanation of the invention by example with reference to the accompanying drawings, which depict:

figure 1 - floor plan with several separate from each other storage areas, driveway and gate areas, as well as the plane of the walls of the extinguishing agent;

figure 2 - laid in the building near the roof plane, a system of horizontal pipes with a network of pipelines for supplying a fire extinguishing medium into the vertical supports of the building, control sections, control units, a section of water valves and matrix control, in isometric view;

figure 3 - connection diagram of the control units with an annular or sectional pipeline and vertical supports;

figa-4d is a section of the support with options for the distribution of couplings and devices for the release of extinguishing agents around the periphery of the supports;

figa and 5b are diagrams of options for mounting supports;

6 is a diagram of the location of the detection means in the planes of the walls of the extinguishing agent;

7 is a control unit in the form of a dry version;

Fig.8 is a longitudinal section of the control unit according to Fig.7;

Fig.9 is a longitudinal section of the control unit in the form of a membrane valve;

figure 10 - control unit in the form of a wet version; and

11 is a diagram of a method according to the invention.

1 shows a plan of a building 1 in which an apparatus according to the invention is integrated. Building 1 is divided into various fire sections. So, for example, in building 1, a block warehouse can be installed at ground level as a fire section A and a multi-seater system with a winding passage in the form of a fire section B, access to which is provided from the driveway passing through building 1 as a fire section C through in the wall of the gate zone structure as fire section D. This distribution is given as an example and may also have a different zoning principle.

Bearing and non-bearing vertical supports 2 of the building 1 are made hollow and form pipelines 3 for the supply of extinguishing agents. Relative to individual fire sections, the supports 2 are arranged to each other so that they limit the fire sections A, B, C in a straight line with uniform distances from each other. However, it is also possible that the vertical supports 2 themselves separate separate fire sections. It should only be ensured that the supports 2 can together form a uniform rectilinear raster in and around the respective fire section.

The device according to the invention essentially consists of at least one reservoir for the extinguishing agent for storing the extinguishing agent, for example water, from at least one system for generating the required extinguishing agent pressure from 0.5 to 20 bar, a main valve and valves, which relate to in general, to the valve section for the extinguishing agent indicated by 4, horizontal, installed in any plane of the structure, for example, near the roof, pipe system 5 with parallel pipelines 6 for supplying negasyaschego means in lines 3 vertical supports 2, of the control block 7 which are connected to a pipe system 5 and to the vertical support 2, devices 8 release extinguishing agent, as well as means 9 detection and designated fire alarm center with integrated logic array 10.

The extinguishing medium valve portion 4 is connected through the main pipe 11 to the pipe system 5, which passes through the structure 1, for example, near the roof structure. The pipe system 5 can be made in the form of an annular or sectional pipeline 12, which is horizontally branched using parallel pipelines 6.

Vertical supports 2 are connected to an annular or sectional pipeline 12 and / or parallel pipelines 6, as shown in FIGS. 2 and 3. Each vertical support 2 is connected via a short horizontal branch 13 to a control unit 7.1 ... 7.n, which through a branch 14 with a pipe elbow 15 enters the annular or sectional pipe 12.

The vertical supports 2 preferably consist of a steel pipe and are provided with internal thread couplings 16 installed with a uniform distance from each other, which are installed in the pipe casing of the supports with a material short circuit, for example by welding. The couplings 16 are screwed tightly relative to the fluid and pressure of the extinguishing agent discharge device 8, preferably spray nozzles, and are accordingly oriented in the desired spray direction. Naturally, you can also use the vertical supports 2 of impervious to water concrete without departing from the idea of the invention.

Figures 4a-4d show, by way of example, the distribution of the couplings 16 around the periphery of the vertical supports 2. Screwed into the couplings 16 of the extinguishing medium 8, the amount of the extinguishing medium is provided that provides a homogeneous and sufficiently thick wall of the extinguishing medium from the extinguishing medium mist between the supports 2 , in order to achieve the required fire resistance for the respective fire sections A-D corresponding to the fire wall.

The distribution and number of extinguishing agent release devices 8 are selected depending on the size of the area to be protected, the specified fire resistance time and the required volume of the extinguishing agent to be created. It was found that for an area of, for example, 100 m ² , a total of four extinguishing agent devices 8 are sufficient to create a 1.5 m thick and homogeneous extinguishing agent wall from the extinguishing agent mist. For example, only two or up to six fire extinguishing agent release devices 8 may be provided that are capable of throwing the fire extinguishing agent in different directions depending on requirements. As the extinguishing agent discharge devices 8, water spray nozzles, fine spray nozzles, nozzles with a full spray cone with a filter located in front of them, or controllable nozzles are equally suitable.

The vertical distance between the devices 8 release extinguishing agent, it is advisable to coordinate with the height of the racks installed in the fire sections A and B of multi-tier warehouses.

Figures 5a and 5b show mounting options for the vertical supports 2 on the bottom plate 17 of building 1. In the case where the vertical supports 2 are mounted on the bottom plate 17, the support 2 is closed liquid tight with the support plate 18, which is fastened with threaded rods 19 in the cage in the bottom plate 17. The vertical support 2 has a coupling 20 near its base plate 18 to accommodate a ventilation or drain device not shown. If the vertical support 2 is mounted directly in the bottom plate 17, a drain device 46 with drainage should be provided (see FIG. 5b).

With each control unit 7.1 ... 7.n, a detection means 9 can be connected, for example a fiber-reinforced hydrothermal hose that is laid in a zigzag pattern in the vertical planes E.1 ... E.n passing through the supports 2. Hoses installed at regular distances from each other. held, for example, under control pressure, for example, 0.5-20 bar, preferably 3.0-4.0 bar, which is created using an external medium such as gas, preferably compressed air, or a liquid, preferably water. However, it is also possible to use a thermal fire engine instead of a hydrothermal hose or, for example, a pressure sensor 47 that directly controls the pipe 3 of the supports 2. In this case, the pressure sensors 47 are connected to a logic matrix 10, which drives the corresponding control units 7.1 ... 7.n (see figure 3).

Figure 6 shows the laying of a hydrothermal hose in the vertical planes E.1 ... E.n. passing around the fire sections.

The hydrothermal hose acts as a linear thermal fire engine, in which a pressure of 0.5 to 20 bar is created, in this case 4 bar. The control medium may be gaseous, preferably compressed air, or liquid, preferably water.

As soon as in one plane E.1 ... E.n the temperature rises due to thermal load due to the action of the flame, this leads to an increase in the pressure of the control medium in the hose, due to which the hose bursts and thereby causes a pressure drop in the control medium. This pressure drop acts on the corresponding control unit 7.1 ... 7.n, which provides the opening of the extinguishing agent supply and frees up the access of the extinguishing agent under pressure up to 16 bar to the vertical supports 2 to the respective extinguishing device discharge devices 8.

In addition, the control unit 7.1 ... 7.n is connected to the logical matrix 10 of the central point of the fire alarm and signals the activation of the device 8 release fire extinguishing means to create a wall of water, for example, in the plane E.1. The logical matrix 10 determines the other E.n planes related to the respective fire hazardous section A and includes the control units 7.n related to these planes, which, in turn, ensure the opening of the extinguishing agent supply to the corresponding E.n. planes. Thus, the corresponding fire hazard section is enclosed, so that the fire cannot spread to the adjacent sections of building 1.

The fire resistance of individual sections can be further enhanced if at least one more detection means connected to the logic matrix 10 is provided inside the fire hazard sections, such as, for example, a smoke detector. As soon as it detects a fire hazard, the logic matrix 10 controls the control units 7.n related to the fire source, which supply fire extinguishing means for creating vertical and / or horizontal walls of the fire extinguisher in the spray planes surrounding the fire center between the vertical supports 2. It is advisable to fix at least one additional detection tool over a building installation, for example, a multi-storey warehouse in the area of the roof of a building 1. Naturally, along with the signal Other means of detection, such as mechanical, hydraulic, thermal, optical systems, such as sprinkler systems, are also suitable for the smoke detector.

The scope of the invention also includes the case when the entire multi-tier warehouse, further fenced along the planes E.1 ... E.n with the help of the walls of the extinguishing agent, is additionally controlled by means of a separate fire-fighting installation. The implementation of this fire fighting installation may correspond, for example, to the installation specified in DE 102006024088 B3 or it may be a sprinkler installation commercially available.

7 and 8 show the design of the control unit 7.1-7.n in the form of a dry version. The control unit 7.1 ... 7.n consists essentially of a diaphragm valve 23 and a control valve 24 provided with an inlet and outlet conduit 21, respectively. The diaphragm valve 23 has a diaphragm chamber 25 in which a membrane 26 is fixed between the casing 27 of the diaphragm valve 23 and the closure of the diaphragm chamber 25 with a lid 28. In the closed state, the membrane 28 fits snugly on the valve seat 29 of the membrane valve 23 and locks the extinguishing agent into the outlet chamber 30 of the membrane valve 23.

On the cover 28, there is a connecting element 31 for a compressed air hose 32, which is connected to a compressed air source not shown, as well as a control valve 24. A compressed air source presses the membrane 26 against the valve seat 29 and loads connected to the control valve 24, closed on the end side end element 33 hydrothermal hose. The compressed air hose and the hydrothermal hose are protected from each other by means of a check valve 34. The hose can be closed using a ball valve 35 relative to the control valve 24. Also, by means of a ball valve 36, it is possible to block the extinguishing agent to the diaphragm valve 23.

As soon as the pressure drops in the hose, the membrane 26 is unloaded and leaves due to the pressure of the extinguishing agent from the valve seat 29. Through the nozzle 37 and the fluid channels 38 embedded in the membrane 26 between the control valve 24 and the exhaust chamber 30, the still existing in the membrane chamber 25 and in the control valve 24 is air, so that a quick actuation of the membrane valve 23 is ensured.

The extinguishing agent enters through the membrane chamber 25 into the exhaust chamber 30 and flows through the vertical supports 2 to the extinguishing agent discharge devices 8, from which the extinguishing agent is sprayed in the E.1 ... E.n planes to form the wall of the extinguishing agent.

A pressure sensor 39 is installed in the control valve 24 or the connecting element 31, which detects a pressure drop and sends a signal through the connecting line 40 to the converter 41, which is connected to the main water valve of the extinguishing medium valve section 4 through the control unit. This unit opens the main water valve when a signal is received.

Instead of the diaphragm valve 23, it is also possible to use a magnetic valve 42 (see Fig. 9) in the control unit 7.1 ... 7.n. In this case, the valve control is initiated by a pressure-detecting sensor 39 or by means of a pressure switch 47, which actuates the trigger 43 in the trigger chamber 44 of the magnetic valve 42 to open the valve seat and release the extinguishing agent.

Figure 10 shows the control unit 7.1 ... 7.n in the form of a wet version. In this case, a sensor 39 is not required for measuring the pressure drop and controlling the main water valve. The extinguishing agent reaches without additional locking up to the membrane chamber 25 and presses the membrane with the seal against the valve seat 29. Otherwise, the design corresponds to the control unit 7.1 according to Fig.7.

Figure 11 shows the progress of the method according to the invention. Building 1 is divided in accordance with the existing conditions into several fire hazardous sections A-D. In the example, there is a section A for a multi-tier warehouse, a section B for a zigzag multi-seater system, a section C for connecting sections A and B of access roads for transporting goods to be stored, and a section D for gates for entering and leaving building 1.

Sections A-D are surrounded by vertical spray planes E.1 ... E.n, which extend between the vertical supports 2 of structure 1.

Detection means 9, such as heat detectors, pass through each of these spraying sections E.1 ... E.n, and temperature and pressure are monitored so that each AD section is separated from the others and is intended to be surrounded by an imaginary fire wall in the form of a wall extinguishing agent from spray mist.

Each spray plane is matched with at least one control unit 7.1 ... 7.n, which are connected to the logic matrix 10 of the central fire alarm point. If one of the detection means 9 detects a pressure drop due to fire in one of the sections A-D in one spray plane E.1 ... E.n, then the pressure sensor 39 sends this information after converting it into a digital signal into a logical matrix 10. It processes the signal determining the E.1 ... Еn plane and supports 2 related to the corresponding section of the plane. Logic matrix 10 opens the main valve of the extinguisher means section 4 of the valve 4 made in the form of a magnetic valve and controls with ablating blocks 7.1 ... 7.n with the aim of automatically creating vertical walls of the extinguishing agent in the planes E.1 ... E.n between the supports 2. Then the fire hazard section is surrounded on all sides by a homogeneous dense wall of the extinguishing agent from the fog of the extinguishing agent, which acts as a fire wall .

If a fire does not occur near one of the monitored planes E.1 ... E.n, but inside, for example, a multi-tier warehouse installed in section A, then a fire or a fire hazard is detected using another means 45 located above the multi-tier warehouse, connected to the logic matrix 10 detection, for example, smoke detector, and is transmitted as a signal to the logic matrix 10.

The logic matrix 10, as mentioned above, issues a command to open the main valve of the section 4 of the extinguishing valve and controls the corresponding control units 7.1 ... 7.n in order to create walls of the extinguishing medium along the corresponding section.

After surrounding the corresponding section with the walls of the extinguishing agent, it is naturally possible to carry out the fight against fire or fire in a localized volume. Particularly preferably, if the fight against fire in a localized volume is carried out by the method specified in DE 102006024688 B3.

However, the logic matrix 10 can also be triggered using a thermal line detector and / or an automatic detector. It can also be manually switched on and off using the reset button.

Other extinguishing agents, such as inert gases, chemical gases, powders or foams, can also be used as a fire extinguishing agent. It is clear that the device according to the invention must in this case be coordinated with an appropriate extinguishing agent to carry out the method.

The solution according to the invention provides the very important advantage that the structure 1 can be constructed using a plurality of vertical posts 2 in the form of a light structure, so that a significant amount of building materials can be saved and at the same time the safety and resistance to fire of the building can be increased.

In addition, the solution according to the invention makes it possible to use classical fire extinguishing methods due to the fact that the vertical conductive extinguishing means of the rack 2 have water extraction devices, such as fittings or hydrants, to which appropriate fire extinguishing devices can be connected without problems.

To prevent the effects of corrosion and aging in the device according to the invention, it may further be possible to mix appropriate suitable means in the extinguishing agent to reduce corrosion.

List of Reference Items

1 Building

2 vertical supports for 1

3 Pipelines in 2

4 Area of extinguishing agent valves

5 Pipe system

6 Parallel pipelines in 5

7.1 ... 7.n Control units

8 Extinguishing media release devices

9 Detector

10 Logical matrix

11 Main pipeline

12 Ring or sectional pipeline

13 Horizontal branch pipe

14 Vertical branch pipe

15 Pipe elbow from 14

16 Couplings on 2

17 Bottom plate from 1

18 Base plate

19 Threaded rods

20 Drain coupling

21 Inlet pipe for 23

22 Outlet pipe for 23

23 diaphragm valve

24 check valve

25 Membrane chamber

26 Membrane

27 Housing from 23

28 Cover

29 valve seat

30 exhaust chamber at 23

31 Connecting element

32 Compressed air hose

33 Tip

34 Check valve

35 ball valve for 24

36 ball valve for 23

37 Nozzle in 26

38 Fluid channels

39 pressure sensor

40 Trunk

41 Converter

42 Solenoid valve

43 Trigger

44 exhaust chamber

45 Another means of detection

46 water drain hose

47 pressure switch

A, B, C, D Fire hazardous sections

E.1 ... E.n Spray planes for the walls of the extinguishing agent

Claims (38)

1. A method of fire fighting localized in volume and / or area of fire fighting in fire-hazardous areas of buildings and installations, in which the fire-extinguishing agent is supplied from a piping system horizontally located in the structure with branches and shut-off valves to the vertical hollow structure supports from the section of the fire-extinguishing valve and in the event of a fire, finely spray or spray under pressure in a certain amount and with a certain duration using spray nozzles, while locking valves Panes, after detecting a fire source, are opened using detection means to unlock the extinguishing agent, generate an initiation signal, and at the same time, with the help of a central control center, give an alarm, give at least one fire warning to the relief site, turn on the extinguishing agent, and turn off the electrical and fire-hazardous installations, characterized in that around the source of fire and / or in fire-hazardous areas create at least one wall of extinguishing agent from sprayed fog to prevent the spread of the thermal load to other zones along at least one vertical and / or horizontal spray plane passing between the poles, respectively, the fire hazard zone and supported by detection means, and / or at least one additional a wall of extinguishing agent made of spray fog to protect and cool the escape routes, access roads, openings in fire walls and technical equipment inside the building I along the spray plane passing between the conductive extinguishing agent supports belonging to them. 2. The method according to claim 1, characterized in that the wall of the extinguishing agent is created in the horizontal and / or vertical direction around the source of fire, respectively, of the fire hazard zone. 3. The method according to claim 1 or 2, characterized in that the following additional operations are provided:
a) the distribution of the structural supports that carry the extinguishing agent to fire hazard zones, escape routes, access roads, openings in fire walls and technical devices;
b) the combination of fire hazard zones and conductive suppressant means supports in large volume sections of the control with related devices of the release of the extinguishing agent,
c) the formation of planes for the walls of the extinguishing medium between the vertical supports related to the fire source, respectively, the fire hazard zone by controlling the extinguishing means releasing devices related to the respective controlled section using the control unit,
d) detecting and determining the location of the fire within the controlled area using detection means that transmit changes in temperature, smoke and / or pressure to the initiating control units and to the central control room,
f) determining the vertical supports between which a vertical and / or horizontal wall of the extinguishing agent is created, while blocking the corresponding control units,
f) converting the change in temperature, smoke and / or pressure according to step d) into control parameters and activating control units for opening and / or closing the extinguishing agent exhaust devices related to the vertical supports to create the wall of the extinguishing agent. 4. The method according to claim 1 or 2, characterized in that the control units are controlled using a logic matrix that determines the supports related to the fire source, respectively, to the fire hazard zone, block and / or release the corresponding control units in order to connect or lock extinguishing agent. 5. The method according to claim 4, characterized in that all the control units and devices for signaling an alarm, turning off electrical installations and / or transmitting signals to the fire department are controlled by a logical matrix. 6. The method according to claim 4, characterized in that the logic matrix in the event of a fire first opens the valve section of the extinguishing agent and then activates the corresponding control units with a time delay. 7. The method according to claim 4, characterized in that the logic matrix is activated manually. 8. The method according to claim 4, characterized in that the logic matrix is activated using a linear heating detector and / or an automatic alarm, preferably a smoke detector. 9. The method according to claim 4, characterized in that the logic matrix is disabled using the reset button. 10. The method according to claim 1, characterized in that water, inert gases, chemical gases, powders or foams are used as an extinguishing agent. 11. The method according to claim 10, characterized in that means are added to the extinguishing agent to reduce, respectively, prevent corrosion and aging of the pipe system, piping in upright posts and fittings. 12. The method according to claim 1, characterized in that as a means of initiation or detection, a hose of thermoplastic material with fiber reinforcement is used, which is held under control pressure from 0.5 to 20 bar, preferably from 3.0 to 4.0 bar . 13. The method according to p. 12, characterized in that the control pressure in the hose is created using an external medium, such as gas, preferably compressed air, or a liquid, preferably water. 14. The method according to claim 1, characterized in that the extinguishing agent is released under pressure from 0.5 to 20 bar. 15. The method according to claim 1, characterized in that the detection means is laid in a zigzag pattern between the planes passing through the vertical supports and is sealed at the ends. 16. The method according to claim 1, characterized in that mechanical, hydraulic, thermal, optical systems, for example sprinkler systems with pyrolytic sensors, are used as means of initiation and detection. 17. The method according to claim 1, characterized in that it provides the possibility of free regulation of the quantity and distribution of the extinguishing agent and selective use depending on the course of the fire. 18. The method according to claim 1, characterized in that as a horizontal piping system, a dry or wet piping system is integrated into the network in any plane of the structure with actively connected to it, turned on and off with the help of control units, ascending or descending vertical supports with bearing nozzles for extinguishing branches for supplying a fire extinguishing agent in the fire zone and between supports. 19. The method according to claim 1, characterized in that the extinguishing agent is sprayed or sprayed in a substantially horizontal direction of ejection from the exhaust devices of the extinguishing agent. 20. The device for implementing the method according to claim 1, containing at least one reservoir for storing at least one extinguishing agent, at least one system for creating pressure extinguishing agent, located horizontally in any plane of the structure of the branched pipe system (5) for the supply of the extinguishing agent through the main valve for water into many vertical hollow supports (2) of the structure (1), and the supports (2) are equipped with devices (8) for the release of the extinguishing agent, valves for opening and closing the pipe wires, means (9) for fire detection, a fire detector for processing and transmitting a fire warning, as well as deploying fire measures in various fire hazardous sections (A, B, C, D) of a building (1), characterized in that the vertical hollow supports (2) around and / or in at least one of the fire sections, vertical and / or horizontal spray planes (E.1 ... E.n) are formed, with at least detection means and a control unit (9) attached to the respective spray plane 7.1 ... 7.n) to turn on and off I devices (8) release the extinguishing agent, and all the planes (E.1 ... E.n) spray and control units (7.1 ... 7.n) have a common logical matrix (10) to simultaneously initiate the fencing of the fire, respectively, fire hazardous area and for the protection and cooling of escape routes, openings in fire walls and technological devices using fire extinguishing agent walls. 21. The device according to claim 20, characterized in that the spray plane (E.1 ... E.n) is equipped with at least one additional control of the internal space of the fire hazard section (A, B, C, D) connected to the logical matrix ( 10) means (45) of detection. 22. The device according to p. 21, characterized in that the additional means (45) of detection is a mechanical, hydraulic, thermal, optical system, such as a sprinkler system or smoke detector. 23. The device according to claim 20, characterized in that the vertical supports (2) are located at a distance from each other in a straight line. 24. The device according to claim 20, characterized in that in each control unit (7.1 ... 7.n) there is a sensor (39) for measuring changes in pressure and temperature, which is connected to a logic matrix (10) for controlling the main valve of extinguishing water through adjustment block. 25. The device according to claim 20, characterized in that the logic matrix (10) is connected to a signal valve, a signal device for fire protection and with a device for disconnecting electrical or other fire hazardous installations. 26. The device according to claim 20, characterized in that the logic matrix (10) is equipped with a switch (47) for manual initiation. 27. The device according to claim 20, characterized in that the horizontal system (5) of pipes and vertical supports (2) are dry, and the device (8) for the release of the extinguishing agent is open. 28. The device according to claim 20, characterized in that the horizontal system (5) of pipes and vertical supports (2) are wet up to the control unit (7.1 ... 7.n). 29. The device according to claim 20, characterized in that the devices (8) for extinguishing the fire extinguishing agent are water spray nozzles, fine spray nozzles, nozzles with a full spray cone with a filter installed in front of them or controlled nozzles that are located separately or in combination with each other on vertical supports so that their discharge direction is oriented essentially in the horizontal direction and they form a wall of the extinguishing agent. 30. The device according to claim 20, characterized in that the device (8) release fire extinguishing means located next to each other supports (2) are directed in a plane opposite to each other. 31. The device according to claim 20, characterized in that the control unit (7.1 ... 7.n) consists of a membrane valve (23) equipped with an inlet and outlet pipe (21, 22), which has a membrane chamber (25) with a fixed the membrane (26) and the outlet chamber (30) closed by the valve seat (29) and the membrane (26), which closes or opens the inlet pipe (21) of the ball valve (36) connected to the membrane chamber (25) of the membrane valve through a control valve (24) and a check valve (34) containing the compressed medium of the metal hose (32) for loading Nia membrane pilot pressure hose which is connected downstream of the check valve (34) with a metal hose (32) and the outlet chamber (30) is provided with the possibility of locking the hose via a ball valve (35). 32. The device according to p, characterized in that the membrane (26) is equipped with a nozzle (37) for equalizing the pressure between the membrane chamber (25) and the exhaust chamber (30). 33. The device according to p, characterized in that the control valve (24) is connected bypassing the membrane chamber (32) through the channels (38) for the fluid directly with the exhaust chamber (30). 34. The device according to p. 31, characterized in that on the control valve (24) or on the connecting element (31) of the hose for measuring the pressure change of the foreign medium is a pressure sensor (39), which is through a converter (41) and a logic matrix (10) ) is connected to the control unit for controlling the main water valve. 35. The device according to claim 20, characterized in that the control unit (7.1 ... 7.n) consists of a solenoid valve (42) equipped with an inlet and outlet pipe (21; 22) and a relay (47) connected in front of the solenoid valve (42) pressure, moreover, the magnetic valve (42) has an exhaust chamber (44) with an electromagnetic trigger mechanism (43), which is connected to the detection means (9), and a ball valve (35, 36) that locks or opens the inlet pipe (20). 36. The device according to clause 35, wherein the pressure switch (47) is connected to a logical matrix (10). 37. The device according to p. 35, characterized in that the pressure switch (47) directly controls the pipeline (3) of the vertical support (2) and is connected to it. 38. The device according to claim 20, characterized in that on the vertical supports (2) there are fittings for draining water, hydrants or similar devices for extracting water for secondary fire fighting.

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