RU2694852C1 - Method for increasing speed of a sprinkler air fire extinguishing installation (versions) and a device for its implementation (versions) - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: invention relates to the field of stationary equipment, namely to sprinkler air and sprinkler-drencher air fire extinguishing installations. Method for increasing the speed of a sprinkler air fire extinguishing installation with one section consists in the fact that in a single-section plant after activation of the sprinkler, accelerated actuation of the air signal valve is provided due to intensive release of pneumatic pressure from the supply and distribution pipelines through the discharge channel, operation of which is carried out at a given air flow velocity in supply and distribution pipelines, and subsequent shutdown of the discharge channel is carried out when the static state of the air medium in the supply and distribution pipelines changes and when a functional duplicating command is generated, which confirms the need to close the discharge channel. In the case of a branched pipeline network, it is divided into separate sections, each of which is equipped with an interlocking device, which is open in standby mode, and after activation of the sprinkler of one of the sections, accelerated actuation of the air signal valve is provided due to blocking of adjacent sections. At the same time the next AFSS functioning algorithm corresponds to the single section algorithm. One-section sprinkler air fire extinguishing installation is equipped with an air flow indicator mounted on a supply pipeline and connected to the first input of the logic control unit, as well as a functional backup device connected to the second input of the logic control unit, and the output of the logic control unit is connected to the normally closed high-speed reset valve installed on the discharge pipeline. At that, for the fact of formation of the functional duplicating command, which confirms necessity of the discharge channel shutoff, the specified pressure in the supply pipeline is accepted or reached, or achieving a predetermined time interval from the moment when the specified speed of the air flow is detected in the supply pipeline, or the water flow of the discharge channel. In case of branched pipeline network it is made of separate sections, at that at the beginning of each section there are successively installed normally open sectional blocking valve and sectional air flow indicator, wherein each sectional air flow alarm is connected to an address device which identifies the triggered sectional air flow alarm, the output of which is connected to the first input of the logical address control unit, to the second input of which is connected a functional duplicating device, and the first group output of the logical address control unit is connected to sectional normally closed high-speed relief valves, and the second group output of the address control unit is connected to sectional normally open blocking valves. At that, for the fact of formation of the functional duplicating command, which confirms the necessity to shut off the sectional discharge channel, the specified pressure in the common supply pipeline is accepted or reached, or achieving a predetermined period of time from the moment when the activated section of the preset speed of the air flow is registered in the supply pipeline, or the activated flow of the activated section by the water flow.

EFFECT: invention discloses a method for increasing the speed of a sprinkler air fire extinguishing installation (versions) and a device for its implementation (versions).

16 cl, 6 dwg

Description

The invention relates to the field of stationary equipment, namely to the sprinkler air and sprinkler-drencher air fire extinguishing installations.

It is known that the main purpose of automatic fire extinguishing installations is extinguishing a fire in a room or technological equipment [Veselov AI, Meshman LM "Automatic fire and explosion protection of chemical and petrochemical industries". M., "Chemistry", 1975; Baburov V.P. and others. "Automatic installation of fire", - M .: Pozhnauka, 2009].

According to paragraph 5.3.2.2 of the joint venture 5.13130.2009 “Fire protection systems. Installation of fire alarm and fire extinguishing automatic. Norms and rules of design "sprinkler and sprinkler-drencher installations are divided into water filled and air.

In standby mode, in water filled sprinkler and deluge sprinkler installations all pipelines are under water pressure; in air sprinkler systems, the supply and distribution pipelines are under excessive pneumatic pressure; under excessive air pressure.

Air sprinkler or air sprinkler-drencher installations are used for rooms with negative temperatures, as well as for rooms in which spills of fire extinguishing substance (hereinafter referred to as OTV) are undesirable in case of damage or false triggering of sprinklers, i.e. minimization of damage from the consequences of false or unauthorized activation of automatic fire extinguishing installations (hereinafter referred to as AUP).

The principle of operation of the air sprinkler installation is as follows. When the sprinkler sprinkler is activated, air outflow begins through its outlet. When the pressure decreases to a certain level, the signal valve is triggered, and the air is forced out of the pipeline network under the influence of water flow pressure.

In an air sprinkler / deluge installation, the supply and distribution pipelines are filled and the water supply to the protected premises or to the technological equipment to be protected is carried out only when both the sprinkler sprinkler and the fire alarm system are activated.

A significant disadvantage of sprinkler air extinguishing installations is their inertia - an extremely long response time, i.e. time from the moment of activation of the sprinkler sprinkler to the appearance of a fire extinguishing agent. The release of the extinguishing agent and, accordingly, the beginning of extinguishing the fire occur with a delay due to the duration of the process of exhausting air, which filled the supply and distribution pipelines. This process can take several minutes and depends on the total capacity of the supply network of the supply and distribution pipelines, the initial air pressure, the response pressure of the sprinkler air valve and the performance factor of the activated sprinkler sprinkler.

According to SP 5.13130.2009 (pp.3.9, 3.119, 5.2.5, 5.2.9), accelerators and exhausters (high-speed relief valves) are used to reduce the response time of all types of sprinkler air installations. However, the noticeable speed of air AUP when using these devices depends primarily on the algorithm for implementing their optimal response, but no specific circuit solutions are proposed in SP 5.13130.2009.

In the Sprinkler air extinguishing installation [Stationare Feuerlo-schanlage: German Application 19601777, IPC А62С 35/62 /, 07.24.97], it is proposed to use a differential pressure sensor, which, with a certain change in pneumatic pressure, simultaneously outputs a control signal to the actuator to minimize the response inertia action of the signal valve and exhauster. The control of the opening of the signal valve and the exhauster can be done electrically, mechanically, hydraulically or pyrotechnically. When the sprinkler reaches the flow of water, the exhauster should close.

A similar device is implemented in a sprinkler air installation, namely in the method and device for launching a fire protection sprinkler installation [Verfaren und Vorrichtung zum Betreiben einer Feuerlosch-Trockensprinkleranlage: Application 19716585 Germany, IPC A62C 35/68, 22.10.98]. The installation is equipped with a valve mounted on the supply pipe and opening on a signal, for example, automatic fire detectors.

It should be noted that the need to maintain pneumatic pressure in the pipeline network of sprinkler air extinguishing installations is caused by the need to issue an informing signal (after the sprinkler signal air valve has been activated) about the fire and to form control commands to start the fire pumps and, if necessary, to control the exhaust, fresh air or smoke ventilation, shutdown of process equipment, etc. The issuance of the informing signal about the fire and the formation of control commands in existing sprinkler air installations is carried out only after the alarm valve is triggered. A sprinkler alarm air valve can only work if the pressure in the pipe network of the sprinkler air system drops significantly, i.e. from the moment the sprinkler sprinkler is triggered, until a fire alarm is issued and the sprinkler signal air valve is actuated, considerable time can occur.

The “Fire Valve System” is known [Russian patent No. 2401148, А62С 35/68 (2006.01), F16K 17/22 (2006.01), publ. 10.10.2010], containing the main network, located after the shut-off valve, which feeds the touch sensors, for example, in the form of sprinklers. The main network is subdivided into secondary networks, each secondary network being separated from the main network by means of an intermediate valve, which prevents water from entering sections of the network where it is not needed, and is able not only to compensate for the pressure drop in the distribution network, but also in the case of Fire detection can fully open.

However, the design of the intermediate valve is very complicated; it additionally includes a cylinder, a throttle, a non-return element, a three-position valve with a small diameter of the bypass channels. If the bypass channels of the three-position valve are blocked, the fire valve system as a whole may fail, i.e. in case of fire, the fire extinguishing agent will not enter the distribution network. In addition, the intermediate valve does not affect the speed of the signal valve, or the accelerated release of air from the supply pipeline and distribution network.

Known "The fire extinguishing system in enclosed spaces" [ed. swith USSR №1263262, IPC A62S 35/00, publ. 10/15/1986], equipped with a by-pass valve, connected at the inlet to the shut-off valve, and at the outlet with control valves, a drain valve, at the inlet connected to the shut-off valve, and at the outlet freely with the atmosphere. Moreover, the control device is connected to the inputs with fire detection sensors in protected premises, the first outputs with control valves, the second output with a starting-off device, the third output with a relief valve and the fourth output with a drain valve.

However, this system, which contains separate sections, can be implemented only for deluge fire extinguishing installations and cannot be implemented in any way with the aim of increasing the speed of air sprinkler AUP.

Known "Installation for extinguishing a fire" [the patent of Russia №2122875, IPC А62С 35/00 (1995.01), publ. 12/10/1998], comprising a high pressure drive unit for the quenching fluid, having an outlet line connected to the existing means of control valves, containing outlet lines to a plurality of existing sections and a number of valves, while the corresponding outlet lines of the means of control valves are designed to be connected with a source of pressure, preferably with a source of fluid, and a number of valves are preferably made transient and interconnected with the possibility of establishing the connection of cells from the section (A) to the outlet pipeline of the drive unit and closing the connections from other fire-prevention sections (B, C, D) to the outlet pipeline of the drive unit by connecting the pressure source to one outlet pipeline for this section (A).

The output piping from the control valve means to the sections is preferably interconnected in pairs (A, B; C, D) by means of a transition valve, and these transition valves are interconnected in pairs by means of a transition valve in direct or indirect connection to the output pipeline of the drive unit .

However, this fire extinguishing installation, containing separate sections, can be implemented only for deluge fire extinguishing installations and can in no way increase the speed of air sprinkler AUPs.

Known "Method of controlling the air installation of fire extinguishing and device for its implementation" [patent of Russia No. 2610816, IPC А62С 35/00 (2006.01), publ. 15.02.2017], which includes fire detection, processing information about the status of the sprinkler fire extinguishing sprinkler sprinklers and triggering a signal valve, and it uses sprinkler sprinklers equipped with an actuation control device, and the signal for opening the signal valve is generated by the actuation control device activated sprinkler, while the pipeline network of supply and distribution pipelines can be divided into separate zones, and when In the installation, the supply of fire extinguishing agent is carried out only in the zone from which the signal from the monitoring device of the activated sprinkler is received.

With all the effectiveness of this method and device for its implementation for their implementation requires a fairly complex electronic circuit for their implementation.

Closest to the claimed method of improving the performance of a sprinkler air extinguishing installation (options) and a device for its implementation (options) on a set of features, adopted for the prototype, is the Sprinkler system with start-up blocking [utility model No. 80121, IPC А62С 35/02 ( 2006.01), publ. 27.01.2009], consisting of a network of pipelines, sprinkler sprinklers, a fire alarm and control system, an automatic dosed supply system for a fire extinguishing substance (compressed air (gas), and the hydraulic circuit for supplying a fire extinguishing substance consists of a series-connected supply pipe with a valve, membrane universal valve, supply and distribution pipelines, while at the point farthest from the supply pipe and (or) at the highest points of the pipeline air an exhauster is installed in the filled network, made of an electrically controlled valve with a device for monitoring the level of the environment of the extinguishing agent and equipped with an outlet piping, controlled by detectors of the fire alarm system and releasing air (gas) outside the protected object (room), and at the end of the output piping a mechanical siren (buzzer , whistle) and a silencer.

If the sprinkler is opened before the fire alarm system detectors trigger, the air (gas) is discharged through the opened sprinkler, registering the pressure change in the supply pipeline, generates the “Accident” signal.

The disadvantage of the prototype is the use of a complex multi-structured complex: a deluge-sprinkler signal valve, actuated by a drainage valve that is activated when the fire alarm system detectors are triggered. The inclusion of the exhauster is also provided only from automatic fire detectors. Such a system is devoid of all the advantages of self-sufficiency of sprinkler fire extinguishing installations, but it has the disadvantages inherent in the deluge fire extinguishing installations. Those. for its operation, a sprinkler air extinguishing installation must be necessarily equipped with a fire alarm system, which greatly complicates and increases the cost, both the creation of such a system and its operation. Since the spurious actuation of sprinkler sprinklers is extremely rare, the activation of the sprinkler sprinkler corresponds to the “Fire” phenomenon, not the “Accident” phenomenon, and the earlier the “Fire” signal is given, the earlier people will be notified about it. Consequently, when receiving from the Sprinkler system with blocking the start of the “Accident” signal, the facility personnel will be misled and will not take the necessary measures for timely evacuation, which in turn may cause useless human casualties.

The aim of the claimed invention is timely ahead of fire alarm systems, improving the speed of single- and multi-section air sprinkler fire extinguishing installations, which use traditional sprinklers without the use of detectors and fire alarm systems.

In determining the compliance of the distinctive features of the present invention with the criterion of "inventive step", the prior art was analyzed in the field of water-filled sprinkler and air installations and, in particular, known methods and devices ensuring their speed.

The essence of the proposed method according to claim 1 of the claims, including filling the supply and distribution pipelines with a sprinkler air unit with an extinguishing agent, in standby mode with an extinguishing agent not filled and under pneumatic pressure, is that sprinkler sprinkler accelerated operation of the sprinkler air extinguishing installation provide through intensive the pneumatic pressure from the supply and distribution pipelines is thrown through the discharge channel, which is triggered at a given air flow rate in the supply and distribution pipelines, and the subsequent discharge channel is closed when the static state of the air in the supply and distribution pipelines is changed, confirming the need to overlap the waste channel.

The essence of the inventive method according to additional claim 2 is that in the method for improving the speed of the sprinkler air extinguishing installation according to claim 1 for the fact of forming a functional backup command, confirming the need to shut off the discharge channel, they achieve the specified pressure in the supply pipeline.

The essence of the proposed method according to the additional claim 3 of the claims is that in the Method for increasing the speed of the sprinkler air extinguishing installation according to claim 1, for the fact of forming a functional backup command confirming the need to shut off the discharge channel piping set air speed.

The essence of the inventive method according to additional claim 4 is that in the method for improving the speed of the sprinkler air extinguishing installation according to claim 1, for the fact of forming a functional backup command, confirming the need to shut off the discharge channel, accept the water flow of the discharge channel.

The essence of the proposed method according to claim 5 of the invention, including an extensive network of supply and distribution pipelines, in standby mode, with an extinguishing agent not filled and under pneumatic pressure, and filling with supplying and extinguishing pipelines with an extinguishing agent the fire extinguishing air installation, the branched pipe network of the fire extinguishing air sprinkler installation is divided into separate sections, each You are provided with an interlock open in the standby mode, and after activating the sprinkler sprinkler in one of the sections, the activated section of the fire extinguishing sprinkler unit is accelerated and the fire extinguishing substance is supplied only to this section by blocking the adjacent sections and the intensive discharge of pneumatic pressure from the supply and distribution pipelines activated section through the corresponding discharge channel, the operation of which is carried out at a given air speed Nogo flow in the supply line of the section, and the subsequent overlapping of the discharge channel section produce activated when changing static condition air environment in the supply and distribution piping of this section and in the formation of a functional backup command, confirming the need to overlap the discharge channel.

The essence of the inventive method according to additional claim 6 is that in the Method for improving the speed of the sprinkler air extinguishing installation according to claim 5 for the fact of the formation of a functional backup command confirming the need to shut off the discharge channel of the activated section, they achieve the specified pressure in the common supply pipeline sprinkler air installation of fire extinguishing.

The essence of the proposed method according to the additional claim 7 in the supply pipeline of this section of a given air velocity.

The essence of the proposed method according to the additional claim. .

The essence of the inventive device according to claim 9 on the supply pipeline and connected to the first input of the logic control unit, as well as a functional backup device connected to the second input of the logic control unit, the output of which is connected to a normally closed waste valve, mounted on the waste pipeline.

The essence of the claimed device according to claim 10 is that in the Fire Extinguishing Sprinkler Installation of claim 9, the functional backup device is equipped with a pressure indicator mounted on the supply pipe, the output of which is connected to the second input of the logic control unit.

The essence of the claimed device according to claim 11 is that in the Sprinkler air installation of fire extinguishing according to claim 9 the functional backup device is equipped with a time relay, the input of which is connected to the output of the air flow detector, and the output with the second input of the logic control unit.

The essence of the claimed device according to claim 12 is that in the Fire Extinguishing Sprinkler installation of claim 9, the functional backup device is equipped with a water presence warning device mounted on the waste pipeline, the output of which is connected to the second input of the logic control unit.

The essence of the claimed device according to claim 13 claims, comprising a shut-off device, sprinkler sprinklers, a sprinkler air signal valve, an extensive network of supply and distribution pipelines that are in standby mode under pneumatic pressure, consists of separate sprinkler air extinguishing systems , while at the beginning of each section, a normally open sectional blocking valve and a sectional air flow indicator are sequentially installed, each sectional air flow detector is connected to an addressing device that identifies a triggered airflow detector, the output of which is connected to the first input of a logical address control unit, to the second input of which a duplicate function device is connected, and the first group output of a logical addressable control unit is connected to a normally closed sectional relief valves, and the second group output of the logical address control unit is connected to a normally open section blocking valves.

The essence of the claimed device according to claim 14 is that in the Fire Extinguishing Sprinkler Installation of claim 13, the functional backup device is equipped with a pressure indicator mounted on a common supply pipe, the output of which is connected to the second input of the logical address control unit.

The essence of the claimed device according to claim 15 is that in the Fire Extinguishing Sprinkler installation according to claim 13, the functional backup device is equipped with a time relay, the input of which is connected to the output of sectional signaling devices for air flow, and the output to the second input of the logical address block management.

The essence of the claimed device according to claim 16 of the claims is that in the Fire Extinguishing Sprinkler Installation of claim 13, the functional backup device is equipped with a sectional water presence indicator mounted on each sectional discharge pipeline, each output connected to the second input of the logical address block management.

The technical effect implemented by the claimed method of improving the performance of the sprinkler air fire extinguishing installation according to claim 1 of the claims in comparison with traditional analogues, is as follows:

- a significant increase in speed due to the early detection of the triggering of the sprinkler sprinkler signaling the air flow and the subsequent abrupt release of excess air pressure through the discharge channel;

- issuing a fire warning signal when the air flow indicator is activated, and not when the air signal valve triggers later;

- formation of a control command to open the discharge channel when the air flow indicator is activated, and not when the air signal valve triggers later;

- formation of a functional backup command to overlap the discharge channel.

An additional technical effect on additional claim 2, implemented by the claimed method for improving the speed of the sprinkler air extinguishing installation according to claim 1 The currently adopted control algorithm for the sprinkler air installation of fire extinguishing without the use of additional technical means.

An additional technical effect on additional clause 3, implemented by the claimed method for improving the speed of the sprinkler air fire extinguishing installation according to claim 1, is that the functional backup command to close the discharge channel is formed upon reaching the specified time interval distribution pipelines of a given air speed, which allows to simplify and cheapen the control scheme and the operation of the sprinkler air hydrochloric extinguishing installation.

An additional technical effect on additional clause 4, implemented by the claimed method for improving the speed of the sprinkler air fire extinguishing installation according to claim 1 the channel is formed upon the fact that the water flow reaches the discharge channel allows to close the discharge channel in a timely manner, preventing any unnecessary discharge of water through the discharge channel, no excess air in the pipeline network, and also eliminate complex preliminary calculations of achieving the specified pressure in the supply pipeline or the time from the moment of registration of the specified air flow rate in the supply and distribution pipelines, at which the discharge channel is blocked.

The technical effect realized by the claimed method of improving the performance of the sprinkler air fire extinguishing installation according to claim 5, is that along with the technical effect, implemented by claim 1, the separation of an extensive pipeline network of supply and distribution pipelines into separate sections, the capacity of the pipeline network each of which becomes many times less than the capacity of the pipeline network of the entire sprinkler air extinguishing installation, as a result of which the The speed of the fire extinguishing sprinkler is installed, and the blocking after activation of the sprinkler sprinkler of non-activated sections allows several times to improve the performance of the multi-section fire extinguishing sprinkler with respect to the installation of the same capacity of the branched pipe network not divided into sections.

An additional technical effect on additional claim 6, implemented by the claimed method for improving the speed of the sprinkler air extinguishing installation according to claim 5, is that the functional backup team is formed upon reaching the specified pressure in the common supply pipeline and blocking the sectional discharge channel of that section in which the sprinkler sprinkler is activated, which allows, along with the use of the currently adopted control algorithm of the sprinkler air extinguishing installation, does not involve additional hardware.

An additional technical effect on additional clause 7, implemented by the claimed method for improving the speed of the sprinkler air extinguishing installation according to claim 5, is that the functional backup team is formed upon reaching the specified time interval from the moment of registration of the specified section in the sectional supply pipe of the activated section air flow rates and cover the sectional discharge channel of the section in which the sprinkler irrigator is activated, which allows , along with the simplification and cheapening of the control scheme for the sprinkler air installation of fire extinguishing.

An additional technical effect on additional claim 8, implemented by the claimed method for improving the speed of the sprinkler air fire extinguishing installation according to claim 5 what allows, to provide timely overlapping of the sectional discharge channel, not to allow both the excessive discharge of water through this channel, and the excess residue air and in a sectional pipeline network, to eliminate complex preliminary calculations of achieving a predetermined pressure in a sectional supply pipeline or time since registration in a sectional supply and distribution pipelines of a given air flow rate at which the sectional discharge channel is blocked.

The technical effect realized by the claimed device Sprinkler air extinguishing installation according to claim 9, is that it allows:

- to ensure the issuance of a warning signal about the fire;

- to improve the speed of the sprinkler air installation of fire extinguishing relative to the traditional installation of a similar capacity of the pipeline network;

- to optimize the ratio between the excess water overflow through the waste valve and the excess remaining air volume in the supply and distribution pipelines of the installation.

An additional technical effect on additional clause 10, implemented by the claimed device Sprinkler air fire extinguishing installation according to claim 9 fire extinguishing installations.

An additional technical effect on an additional claim 11, implemented by the claimed device Sprinkler air fire extinguishing installation according to claim 9 .

An additional technical effect on additional clause 12, implemented by the claimed device Sprinkler air fire extinguishing installation according to claim 9, is that the supply of an additional functional backup device with a signaling device for stopping the waste valve ensures its timely shutdown without draining the water through the waste the channel and without the rest of the air in the pipeline network of the sprinkler air extinguishing installation.

The technical effect realized by the claimed device Sprinkler air fire extinguishing installation according to claim 13, is that it allows:

- to ensure the issuance of a warning signal about a fire in a specific section;

- to improve the performance of a multi-compartment sprinkler air installation of fire extinguishing relative to an installation that is not divided into sections and has a similar capacity of an extensive pipe network;

- to optimize the ratio between the excess water overflow through the sectional waste valve and the excess remaining air volume in the inlet and distribution pipelines of the activated section.

An additional technical effect on additional clause 14, implemented by the claimed device. The sprinkler air fire extinguishing installation of clause 13 fire extinguishing sprinkler air units and a fire extinguishing unit in a multi-section air sprinkler unit sheniya.

An additional technical effect on additional clause 15, implemented by the claimed device Sprinkler air fire extinguishing installation according to clause 13 of the claims, is that the supply of an additional functional redundant time relay device to overlap the sectional waste valve allows using a simplified and inexpensive control scheme of traditional sprinkler installations fire extinguishing and in multisection sprinkler installation of fire extinguishing.

An additional technical effect on additional clause 16, implemented by the claimed device Sprinkler air fire extinguishing installation according to claim 13, is that supplying an additional functional backup device with sectional water presence alarms to shut off the corresponding sectional relief valves allows it to be timely shut off without draining water through the sectional discharge channel and without the rest of the air in the sectional piping network of the sprinkler air fire extinguishing installation

Thus, the distinctive features of the proposed technical solutions are new and meet the criterion of "novelty."

Analysis of other technical solutions showed that the known methods and devices do not solve the problems noted above, which are solved by the claimed method and device.

Based on the above we can conclude that the proposed technical solution meets the criterion of "inventive step", and the invention itself is new.

The device presented in figures 1-3, is used to improve the performance of single-section sprinkler air fire extinguishing installations.

The figure 1 is presented in accordance with paragraphs. 9 and 10 of the claims structural diagram of the device. The device shown in figure 1 consists of a sprinkler air signal valve 1, a locking device 2, sprinkler sprinklers 3, a pressure alarm 4, which serves as a functional backup device, an air flow alarm 5, a logic control unit 6, a normally closed waste valve 7, a waste channel 8, supply 9 and distribution 10 pipelines. Sprinkler sprinklers 3 are mounted on distribution pipes 10. The control unit 6 is designed to turn on and off the normally closed discharge channel, which is a waste pipe 8 with a discharge valve 7 mounted on it.

In standby mode, the sprinkler air signal valve 1 is closed. The power supply 9 and distribution 10 pipelines are not filled with water and a certain pneumatic pressure is maintained in them.

In the event of a fire, when any sprinkler 3 is triggered in the feed 9 and 10 distribution pipelines, air flows toward the actuated sprinkler. At the same time, the air flow indicator 5 is activated (i.e., a significant increase in speed occurs due to early detection of the sprinkler sprinkler operation, and not when the sprinkler air signal valve is triggered) and subsequent abrupt discharge of overpressure through the discharge channel, and a fire signal is transmitted ( figure 1 is not shown). The corresponding information about the activation of the air flow detector 5 also enters the first input of the logic control unit 6, from the first output of which a control pulse is sent to the normally closed relief valve 7 — the valve opens. When a waste valve 7 is triggered, the pneumatic pressure in the supply 9 and distribution 10 pipelines is drastically reduced (discharged through the discharge channel), and when a certain pressure is reached, the sprinkler air alarm valve 1 is activated, and therefore, the fire extinguishing sprinkler installation and the distribution 9 10 pipelines begin to flow water. As the pipelines 9 and 10 are filled with water, the pressure in them increases, which leads to more intensive release of air from them through the discharge valve 7, and consequently, more intensive filling of pipelines 9 and 10 with water. Finally, when the pressure in pipelines 9 and 10 exceeds the initial , corresponding to the duty mode, the pressure indicator 4, which acts as a functional backup device, will generate a signal at the second input of the logic control unit 6, from the first output of which a control pulse is output to close the reset valve 7, i.e. to return it to its original on-duty closed state, thereby preventing unwanted water flow from it. Fire extinguishing agent, filling the supply 9 and distribution 10 pipelines, through activated sprinklers is supplied to extinguish the fire.

Thus, the claimed device Sprinkler air fire extinguishing installation according to claim 9, shown in figure 1, allows for the issuance of a fire alarm signal, improve the performance of the fire extinguishing air sprinkler installation relative to the traditional installation of a similar network capacity and optimize the ratio between excess water overflow through the waste valve and excessive preserved air volume in the supply and distribution pipelines of the installation, and the claimed device The sprinkler air fire extinguishing installation according to claim 10, shown in FIG. 1, along with the advantages in accordance with claim 9, makes it possible to use the currently familiar control functions of traditional fire extinguishing sprinkler installations.

The figure 2 is presented in accordance with paragraphs. 9 and 11 of the claims structural diagram of the device. Sprinkler installation of fire extinguishing in PP. 9 and 11, shown in FIG. 2, differs from the fire extinguishing sprinkler installation shown in FIG. 1, in that instead of a pressure alarm 4, a time relay 11 is used, which serves as a functional backup device.

In standby mode, the sprinkler signal valve 1 is closed. Feed 9 and distribution 10 pipelines are not filled with water, and they maintain a certain pneumatic pressure. In the event of a fire, when any sprinkler 3 is triggered in the feed 9 and 10 distribution pipelines, air flows toward the actuated sprinkler. At the same time, the air flow indicator 5 is activated (i.e., a significant increase in speed occurs due to early detection of the sprinkler sprinkler operation, and not when the sprinkler air signal valve is activated), and the corresponding information is fed to the first input of the logic control unit 6, from the first output of which a control pulse is issued to the normally closed waste valve 7 - the valve opens. At the same time, the signal from the activated air flow indicator 5 is sent to start of time relay 11. When the relief valve 7 is activated, the pneumatic pressure in the supply 9 and distribution 10 pipelines decreases sharply (reset through the discharge channel), and when a certain pressure is reached, the sprinkler air alarm valve 1 is activated, and therefore, the fire extinguishing sprinkler installation, and water begins to flow into the supply 9 and distribution 10 pipelines. As pipelines 9 and 10 are filled with water, the pressure in them increases, which leads to more intensive discharge of air through them through the discharge valve 7, and, consequently, more intensive filling of pipelines 9 and 10 with water. Finally, after a certain time interval since the start of the time relay calculated taking into account the length of the pipeline system, its capacity, operating pressure and other parameters of the fire extinguishing sprinkler installation, a time relay, acting as a functional backup device, will generate a signal in volts swarm input control logic unit 6, a first output which is issued the command pulse to the control unit 6, which form the control pulse for closing the relief valve 7, i.e. to return it to its original on-duty closed state, thereby preventing unwanted water flow from it. Fire extinguishing agent, filling the supply 9 and distribution 10 pipelines, through activated sprinklers is supplied to extinguish the fire.

Thus, the claimed device Sprinkler air fire extinguishing installation according to claim 11, shown in figure 2, along with the advantages of paragraph 9, allows the use of a simplified and inexpensive control scheme of sprinkler air fire extinguishing installations.

The figure 3 is presented in accordance with paragraphs. 9 and 12 formulas block diagram of the device. The fire extinguishing sprinkler installation according to claim 5, shown in FIG. 3, differs from the fire extinguishing sprinkler installation shown in FIG. 1, in that instead of a pressure alarm, a water presence alarm 12 is used, which serves as a functional backup device.

In standby mode, the sprinkler air signal valve 1 is closed. Feed 9 and distribution 10 pipelines are not filled with water, and they maintain a certain pneumatic pressure. In the event of a fire, when any sprinkler 3 is triggered in the feed 9 and 10 distribution pipelines, air flows toward the actuated sprinkler. At the same time, the air flow indicator 5 is activated (i.e., a significant increase in speed occurs due to early detection of the sprinkler sprinkler operation, and not when the sprinkler air signal valve is activated), and the corresponding information is fed to the first input of the logic control unit 6, from the first output of which a control pulse is issued to the normally closed waste valve 7 - the valve opens. When a waste valve 7 is triggered, the pneumatic pressure in the supply 9 and distribution 10 pipelines decreases sharply (discharged through the discharge channel), and when a certain pressure is reached, the sprinkler air alarm valve 1 is activated, and therefore, the fire extinguishing sprinkler installation and the distribution 9 pipelines are starting to flow water. As the pipelines 9 and 10 are filled with water, the pressure in them increases, which leads to more intensive discharge of air through them through the discharge valve 7, and, consequently, more intensive filling of pipelines 9 and 10 with water. Finally, when the water flow reaches the water level indicator 12, acting as a functional redundant device, it will issue a command pulse to the second input of the control unit 6, from the first output of which a control pulse is issued to close the waste valve 7, i.e. to return it to its original on-duty closed state, thereby preventing unwanted water flow from it. Fire extinguishing agent, filling the supply 9 and distribution 10 pipelines, through activated sprinklers is supplied to extinguish the fire.

Thus, the claimed device Sprinkler air fire extinguishing installation according to claim 12, shown in figure 3, along with the advantages of paragraph 9, allows for timely shutdown of the waste valve without draining the water through the discharge channel and without remaining air in the fire extinguishing piping network .

The devices shown in figures 4-6 are used to reduce the response time of a multi-compartment sprinkler air installation, if the piping network has an extensive pipeline structure of large capacity. In this case, the piping network of the sprinkler air installation is divided into a number of sprinkler sections with one signal air valve (with one control unit).

The figure 4 is presented in accordance with paragraphs. 13 and 14 of the claims structural diagram of the device. Compared with the device depicted in FIG. 1, pipeline sections 14, normally open section blockers (section block valves 13) are additionally introduced in the device, which prevent water from entering into non-activated sections, and address device 15, when activated, identifies the activated air flow alarm 5. At the same time, the position of the pressure alarm is located on the common supply pipeline, and it performs the function of a common pressure alarm. The number of sectional blocking blockers (blocking valves 13), gas flow detectors 5, sectional discharge channels, each of which is a sectional discharge pipeline 8 with a sectional discharge valve 7 mounted on it, corresponds to the number of sections of the sprinkler air extinguishing installation.

Normally open sectional blockers (sectional blocking valves 13), which prevent water from entering non-activated sections, are installed at the beginning of each branch of the sectional supply pipeline 9 before the sectional air flow signaling devices 5. Sectional sprinkler sprinklers 3 are mounted on sectional distribution pipelines 10.

In standby mode, the deluge signal air valve 1 is closed. All supply 9 and distribution 10 pipelines are not filled with water, and they maintain a certain pneumatic pressure, and normally open section blockers (section block valves 13), designed to prevent water from entering the non-activated section, are open. The open state of the sectional blockers (sectional blocking valves 13) in standby mode is made for reasons of ensuring the operability of the fire extinguishing sprinkler installation in case of failure of the automatic control option for these valves, since with open sectional blockers (sectional blocking valves 13), the extinguishing agent will in any case be supplied to extinguish the fire.

In the event of a fire, when any of the sectional sprinkler sprinklers 3 are triggered in the sectional supply pipe 9 of the activated section 14, air begins to move in the direction of the activated sprinkler. The movement of air is recorded by a sectional indicator of air flow 5 of the section to which the irrigation sprinkler belongs. When the sectional air flow indicator 5 is triggered (i.e., a significant increase in speed occurs due to early detection of the sprinkler sprinkler operation, and not when the sprinkler air signal valve is triggered) a fire signal is transmitted (not shown in figure 1). Information about the activation of the sectional air flow indicator 5 also enters the addressing device 15, which identifies the activated sectional air flow indicator 5 and issues a control command to the first input of the logical address control unit 6. The first output of the logical address control unit 6 generates a signal to open the normally closed sectional waste valve 7, belonging to the sectional pipe section 14, in which the sprinkler sprinkler 3 has been activated, and this valve opens, and with W open exit - to close normally open sectional blockers (sectional blocking valves 13), while preventing water from entering non-activated sections 14. Therefore, when a sprinkled air alarm valve 1 is triggered, the fire extinguishing substance will flow only to the pipeline section to which the sprinkler sprinkler is operated .

When the sectional waste valve 7 of the activated section is activated, the pneumatic pressure in the sectional supply 9 and distribution 10 pipelines of the activated section sharply decreases (discharged through the discharge channel), and when a certain pressure is reached, the sprinkler air signal valve 1 is activated, and in the supply 9 and distribution 10 pipelines activated section starts to flow water. As the section pipelines 9 and 10 are filled with water of the activated section, the pressure in them increases, which leads to more intensive discharge of air from them through the sectional waste valve 7, and consequently, more intensive filling of pipelines 9 and 10 with water. Finally, when the pressure in the pipelines 9 and 10 of the activated section will exceed the initial, corresponding to the standby mode, the pressure indicator 4, which serves as a functional backup device installed on the common supply pipeline, will give a signal to the W swarm input logical address control unit 6, with the first group output which outputs a control pulse to close the relief valve 7, i.e. to return it to its original on-duty closed state, thereby preventing unwanted water flow from it. The extinguishing agent, filling the supply 9 and distribution 10 pipelines of the activated section, through the activated sprinklers 3 is supplied to extinguish the fire.

Thus, the claimed device Sprinkler air fire extinguishing installation according to claim 13, shown in figure 4, allows for the issuance of a fire warning signal in a particular section, improve the speed of a multi-section fire extinguishing sprinkler air installation with respect to an installation of a similar pipe network that is not divided into sections, and optimize the ratio between the excess water overflow through the sectional waste valve and the excess air volume remaining in the inlet piping and distribution piping installation of an activated section, and the claimed device Sprinkler air fire extinguishing installation according to p. 14, shown in figure 4, along with the advantages of p. 13, allows you to use the currently familiar control functions of traditional sprinkler air sprinkler installations and multi-section sprinkler fire extinguishing installation.

The figure 5 is presented in accordance with paragraphs. 13 and 15 of the claims structural diagram of the device. Sprinkler installation of fire extinguishing in PP. 13 and 15, shown in FIG. 5, differs from the fire extinguishing sprinkler installation shown in FIG. 4, in that instead of the common pressure alarm 4, time relay 11 is used, which serves as a functional backup device.

Normally open sectional blockers (sectional blocking valves 13), designed to prevent water from entering into non-activated sections, are installed at the beginning of each branch of the sectional supply pipe 9 before the sectional airflow signaling devices 5. Sectional sprinkler sprinklers 3 are mounted on sectional distribution pipelines 10.

In standby mode, the sprinkler alarm air valve 1 is closed. All supply 9 and distribution 10 pipelines are not filled with water, and they maintain a certain pneumatic pressure, and normally open section blockers (section block valves 13), designed to prevent water from entering the non-activated section, are open. The open state of the sectional blocking valves 13 in the standby mode is taken for reasons of ensuring the operability of the fire extinguishing sprinkler installation in case of failure of the automatic control option for these valves, since with open sectional blockers (sectional blocking valves 13), the extinguishing agent will in any case be supplied to extinguish the fire.

When triggered by any of the sectional sprinkler sprinklers 3 in the sectional supply pipe 9 of the activated section 14, air begins to move in the direction of the activated sprinkler. Air movement is recorded by a sectional air flow indicator 5 of the section to which the sprinkler belongs (ie, a significant increase in speed occurs due to early detection of the sprinkler sprinkler operation, and not when the sprinkler air signal valve is activated). Information about the activation of the sectional air flow indicator 5 is supplied to the addressing device 15, which identifies the activated sectional airflow indicator 5 and issues a control command to the first input of the logical address control unit 6. From the first output of the logical address control unit 6, a signal is issued to open the normally closed sectional waste valve 7, belonging to the sectional pipeline section 14, in which the sprinkler sprinkler 3 was activated, and from the second outlet - to the normal closure but the open sectional bollards (sectional blocking valve 13), while preventing the flow of water in the non-activated section 14. Therefore, the extinguishing agent when triggered signal sprinklenogo air valve 1 will flow only in the pipe section, which belongs to the triggered sprinklers.

When the sectional waste valve 7 is activated, the pneumatic pressure in sectional supply 9 and distribution 10 pipelines sharply decreases, and when a certain pressure is reached, the sprinkler air signal valve 1 is activated, and water begins to flow into sectional supply 9 and distribution 10 pipelines of the activated section. As the pipelines 9 and 10 are filled with water, the pressure in them increases, which leads to more intensive discharge of air through them through the discharge valve 7, and, consequently, more intensive filling of pipelines 9 and 10 with water. Finally, when time relay 11 is activated, it acts as a functional a duplicate device, the control signal will be sent from it to the second input of the logical address control unit 6, from the first group output of which a control pulse is issued to close the waste valve 7, i.e. to return it to its original on-duty closed state, thereby preventing unwanted water flow from it. Fire extinguishing agent, filling the supply 9 and distribution 10 pipelines of the activated section, through activated sprinklers is supplied to extinguish the fire.

Thus, the claimed device Sprinkler air fire extinguishing installation according to claim 15, shown in FIG. 5, along with the advantages of clause 13, allows the use of a simplified and inexpensive control scheme for traditional sprinkler fire extinguishing installations and in a multi-section fire extinguishing sprinkler installation.

The figure 6 is presented in accordance with paragraphs. 13 and 16 of the claims structural diagram of the device. Sprinkler installation of fire extinguishing in PP. 13 and 16, shown in FIG. 6, differs from the fire extinguishing sprinkler installation shown in FIG. 4, in that instead of the common pressure alarm 4, water 12 detectors are used that act as a functional backup device.

Normally open sectional blocking valves 13, designed to prevent water from entering into non-activated sections, are installed at the beginning of each branch of the supply pipe 9 before the sectional air flow signaling devices 5. Sectional sprinkler sprinklers 3 are mounted on distribution pipes 10. Each water level indicator 12 is installed in close proximity to the relief valve 7.

In standby mode, the sprinkler alarm air valve 1 is closed. All supply 9 and distribution 10 pipelines are not filled with water, and they maintain a certain pneumatic pressure, and normally open sectional blocking valves 13, designed to prevent water from entering into non-activated sections, are open. The open state of the sectional blockers (sectional blocking valves 13) in standby mode is made for reasons of ensuring the operability of the fire extinguishing sprinkler installation in case of failure of the automatic control option for these valves, since with open sectional blockers (sectional blocking valves 13), the extinguishing agent will in any case be supplied to extinguish the fire.

When triggered by any of the sectional sprinkler sprinklers 3 in the sectional supply pipe 9 of the activated section 14, air begins to move in the direction of the activated sprinkler. Air movement is recorded by the air flow indicator 5 of the section to which the sprinkler belongs (ie, a significant increase in speed occurs due to early detection of the sprinkler sprinkler operation, and not when the sprinkler air signal valve is activated). Information about the activation of the sectional air flow indicator 5 is supplied to the addressing device 15, which identifies the activated sectional airflow indicator 5, which issues a control command to the first input of the logical addressing control unit 6. From the first output of the logic control unit 6, a signal is issued to open the normally closed sectional waste the valve 7 belonging to the sectional pipeline section 14, in which the sprinkler sprinkler 3 operated, and from the second outlet - to the closing normally open s sectional bollards (sectional blocking valve 13), while preventing the flow of water in the non-activated section 14. Therefore, the extinguishing agent when triggered signal sprinklenogo air valve 1 will flow only in the pipe section, which belongs to a triggered sprinkler 3.

When the sectional waste valve 7 is activated, the pneumatic pressure in the sectional supply 9 and distribution 10 pipelines sharply decreases, and when a certain pressure is reached, the alarm valve 1 is activated, and water starts to flow into the supply 9 and distribution 10 pipelines of the activated section. As the pipelines 9 and 10 are filled with water, the pressure in them increases, which leads to more intensive discharge of air through them through the discharge valve 7, and, consequently, more intensive filling of pipelines 9 and 10 with water. Finally, when the water flow reaches the sectional water alarm 12 an activated section that performs the role of a functional backup device, it will give a signal to the second input of the logical address control unit 6, from the first group output of which a control pulse is output for closing ektsionnogo relief valve 7 activated section, i.e. to return it to its original on-duty closed state, thereby preventing unwanted water flow from it. Fire extinguishing agent, filling the sectional supply 9 and distribution 10 pipelines of the activated section, through activated sprinklers is supplied to extinguish the fire.

Thus, the claimed device Sprinkler air extinguishing installation according to p. 16, shown in figure 6, along with the advantages of p. 13, allows for timely shutdown of the sectional waste valve without draining the water through the sectional discharge channel and the sprinkler network fire extinguishing installation.

It should be noted that in figures 1 - 6 the air flow detector is activated almost simultaneously with the sprinkler sprinkler actuating, therefore the fire alarm is issued immediately after the sprinkler sprinkler actuates (and not after the sprinkler signal air valve triggers, as is the case in traditional sprinkler air extinguishing systems) ).

It should be borne in mind that the relief valves 7 with a water presence alarm 12 can be mounted in any part of the supply or distribution pipelines in single or multiple versions. When the air flow detector 5 is activated, the air supply to the activated pipeline section 14 is automatically shut off.

The system of dosing and control of air pressure in the pipeline network in figures 1-6 is not shown.

Claims (16)

1. A method of improving the performance of a fire extinguishing sprinkler air installation, including filling the supply and distribution pipelines with a fire extinguishing agent of a single-section fire extinguishing sprinkler air installation, in standby mode with fire extinguishing substance not filled and under pneumatic pressure, characterized in that, after activation of the sprinkler sprinkler, it is activated, the fire activation unit is not filled and under pneumatic pressure, characterized in that the activation speed will be activated by the fire extinguishing agent, which will be activated by the fire extinguishing agent not filled and under pneumatic pressure, characterized in that, after activation of the sprinkler sprinkler, the fire extinguishing agent is not filled and under pneumatic pressure, characterized in that the activation speed will activate the fire extinguishing agent without filling and being under pneumatic pressure, characterized in that the activation speed will activate the fire extinguishing agent without filling and being under pneumatic pressure, characterized in that there will be activated activation of the fire extinguishing agent by filling the fire extinguishing agent fire extinguishing provide due to the intensive discharge of pneumatic pressure from the supply and distribution pipelines through the discharge channel, which is activated at a given air flow rate in the supply and distribution pipelines overlap of the waste channel. 2. The way to increase the speed of the sprinkler air fire extinguishing installation according to claim 1, characterized in that for the fact of the formation of a functional backup command, confirming the need to close the discharge channel, they achieve the achievement of a predetermined pressure in the supply pipeline. 3. A method for improving the performance of a sprinkler air extinguishing installation according to claim 1, characterized in that the fact of forming a functional backup command, confirming the need to shut off the discharge channel, assumes the achievement of a predetermined period of time from the moment of registration of a given air flow rate in the supply pipeline. 4. A method for improving the performance of a sprinkler air extinguishing installation according to claim 1, characterized in that for the fact of the formation of a functional backup command, confirming the need to shut off the discharge channel, they accept the water flow to reach the discharge channel. 5. A method of improving the performance of a fire extinguishing sprinkler air installation, including an extensive network of supply and distribution pipelines, in standby mode with an extinguishing agent not filled and under pneumatic pressure, and filling the supply and distribution pipelines with an extinguishing agent, characterized in that the branched pipeline network of a sprinkler air installation fire extinguishing units are divided into separate sections, each of which is supplied with an open blocking in standby mode After activation of the sprinkler sprinkler in one of the sections, the activated section of the sprinkler air extinguishing unit is accelerated and only the extinguishing agent is supplied to this section due to the blocking of adjacent sections and intensive pneumatic pressure discharge from the supply and distribution pipelines of the activated section through the corresponding discharge channel, which is carried out at a given speed of air flow in the supply pipe of this section, and after uyuschee overlap activated discharge channel section produced when changing the static condition of air in the feed and distribution conduits of the sections and during the formation of a functional backup command, confirming the need to overlap the discharge channel. 6. A method for improving the performance of a fire extinguishing sprinkler unit according to claim 5, characterized in that the formation of a functional backup command, confirming the need to shut off the activated channel of the activated section, makes it necessary to achieve a predetermined pressure in the common supply line of the fire extinguishing sprinkler unit. 7. A method of improving the performance of a sprinkler air extinguishing installation according to claim 5, characterized in that the formation of a functional backup command confirming the need to shut off the activated channel of the activated section is taken to achieve a specified time interval from the moment of registration of a given air flow rate in the supply pipeline of this section . 8. A method for improving the performance of a sprinkler air extinguishing installation according to claim 5, characterized in that the fact of forming a functional backup command, confirming the need to shut off the discharge channel of the activated section, accepts the water flow to reach the discharge channel of this section. 9. A sprinkler air extinguishing installation containing a shut-off device, sprinkler sprinklers, a sprinkler air signal valve supplying and distributing pipelines that are in standby mode under pneumatic pressure, characterized in that it is equipped with an air flow warning device mounted on the supply pipe and connected to the first the input of the logic control unit, as well as the functional backup device connected to the second input of the logic control unit, the output of which th is connected to a normally closed relief valve set to the blow-off conduit. 10. Sprinkler air fire extinguishing installation according to claim 9, characterized in that the functional backup device is equipped with a pressure indicator mounted on the supply pipe, the output of which is connected to the second input of the logic control unit. 11. Sprinkler air fire extinguishing installation according to claim 9, characterized in that the functional backup device is equipped with a time relay, the input of which is connected to the output of the air flow detector, and the output to the second input of the logic control unit. 12. Sprinkler air fire extinguishing installation according to claim 9, characterized in that the functional backup device is equipped with a water presence warning device mounted on the waste pipeline, the output of which is connected to the second input of the logic control unit. 13. Sprinkler air fire extinguishing installation, containing a locking device, sprinkler sprinklers, sprinkler air signal valve, an extensive network of supply and distribution pipelines that are in standby mode under pneumatic pressure, characterized in that it is made of separate sections, at the same time at the beginning of each section a normally open sectional blocking valve and a sectional air flow indicator are installed in series, with each sectional airflow indicator connected to the addressing device that identifies the triggered air flow alarm, the output of which is connected to the first input of the logical address control unit, to the second input of which the functional backup device is connected, and the first group output of the logical addressable control unit is connected to the normally closed sectionalized relief valves, and the second group output the output of the logical address control unit is connected to normally open sectional block valves. 14. Sprinkler air fire extinguishing installation according to claim 13, characterized in that the functional backup device is equipped with a common pressure indicator mounted on a common supply pipe, the output of which is connected to the second input of the logical address control unit. 15. Sprinkler air fire extinguishing installation according to claim 13, characterized in that the functional backup device is equipped with a time relay, the input of which is connected to the output of sectional signaling devices of air flow, and the output - with the second input of the logical address control unit. 16. Sprinkler air fire extinguishing installation according to claim 13, characterized in that the functional backup device is equipped with a sectional water alarm indicator mounted on each sectional discharge pipeline, the output of each of which is connected to the second input of the logical address control unit.

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