RU98334U1 - ATMOSPHERE INERTIZATION SYSTEM IN A CLOSED PROTECTED SPACE - Google Patents

Abstract

 1. The system of inertization of the atmosphere in a closed protected space, comprising: control means (CS), ventilation means (CB) connected to the CS, at least one oxygen concentration meter (ICC) connected to the CS, and located in the protected space, at least one fire detector (PI) connected to the control system, and located in the protected space, at least one pressure meter (ID) connected to the control system, and located in the protected space, at least one sensor human presence (DPL), at least one position sensor (DP) located in the space to be protected, at least one controllable locking device (UCS), at least one room access control device (UKPD) configured to transition between open and closed provisions and equipped with at least one DP and ultrasonic control unit, a node for supplying a mixture containing nitrogen and oxygen (UPAKS) connected to the control system and configured to control the change in the concentration of oxygen in the supplied mixture, at least one controlled valve (CC) , connected to the control system, distribution pipe (RT) connected to the UPAKS and equipped with nozzles in communication with the protected space, and at least one CC, characterized in that the control system is configured to determine fire, oxygen concentration, pressure, position УКДП and the presence of people by means of the CQI, ID, ПИ and ДП, respectively, and with the possibility of turning on / off the УЗУ, УК, UPАКС and СВ and controlling the oxygen concentration of the mixture supplied by UPAKS, so that in case of fire in the protected volume they will be installed

Description

FIELD OF TECHNOLOGY TO WHICH A USEFUL MODEL IS

The utility model relates to the field of fire fighting, and more specifically to automated systems for inertization of the atmosphere in a closed protected space.

BACKGROUND

Means and methods of inertizing the atmosphere in a closed protected space are well known.

The principle of operation of systems for atmospheric inertization is based on the fact that the introduction of a gas mixture with a reduced oxygen content into a closed volume or the displacement of the natural atmosphere from a closed volume by a gas mixture with a low oxygen content reduces the oxygen concentration inside the volume to the level at which the flame is extinguished ignition and / or decay of combustible materials. The quenching effect usually occurs when the oxygen content is below 15 volume percent, and for flammable materials to a content below 12 volume percent. These methods are usually applied at facilities in which the use of liquid fire extinguishing compounds could cause significant damage or lead to serious consequences.

The main technical contradictions that arise when creating such systems are expressed in the fact that with a decrease in the concentration of the mixture used to inert the closed volumes, and with an increase in the rate of its introduction, fire extinguishing efficiency increases, but the safety of fire extinguishing for people inside the enclosed volume decreases in connection with the creation of an atmosphere unsuitable for breathing and local oxygen-poor areas near the outlet pipes. On the other hand, increasing the concentration of the mixture used for inertization, although it can increase safety, it also reduces the fire extinguishing efficiency and creates the risk of damage in the protected space, since high rates of mixture release are required to create an inert atmosphere and the pressure in the enclosed space increases faster than using oxygen-poor mixtures.

A known method and device implementing it for the prevention and / or extinguishing of fires, in which the room is filled with a gas mixture with an oxygen concentration of 10 to 14 vol.% By supplying oxygen-depleted air to an unpressurized room while removing non-oxygen-depleted air from the room, moreover the pressure of the gas mixture in the room is maintained at a level of from 0.001 to 0.01 atm. (RF patent No. 2201775). A disadvantage of the known device that impedes the achievement of the following technical result is that its use for inertization of closed volumes can lead to destruction and death of people from hypoxia.

A known method and device implementing it for the prevention and / or extinguishing of fires, in which continuous partial inertization of the atmosphere in a confined space is carried out, and when a fire occurs, an oxygen-depleted mixture is introduced until the level of complete inertization is achieved (RF patent No. 2212262). A disadvantage of the known device that impedes the achievement of the following technical result is that it is necessary to constantly replenish the inert atmosphere inside the volume and that in case of fire, rapid inertization of the atmosphere in a closed room can lead to death of people from hypoxia and to destructive pressure surges.

There is a method of inertization and a device implementing it to prevent and / or extinguish fires, in which the atmosphere is continuously inert to a basic level of inertization, and if necessary, the degree of inertization is rapidly increased stepwise or in case of fire by introducing a gas displacing oxygen from the buffer tank (RF patent No. 2266767 ) A disadvantage of the known device that impedes the achievement of the following technical result is that the rapid inertization of the atmosphere in a closed room can lead to death of people from hypoxia and to destructive pressure surges.

A known method and device implementing it to prevent and / or extinguish fires, in which a closed volume is continuously purged with a pre-prepared breathable composition comprising nitrogen or an inert gas other than nitrogen, having a gas composition having inert properties and from 12% to 18% oxygen while extinguishing the fire, a composition containing from 8% to 16.8% oxygen is introduced into the volume (RF patent No. 2301095). A disadvantage of the known device that impedes the achievement of the following technical result is that during fast inertization of confined volumes, destructive pressure surges can occur, and extinguishing fires with mixtures with an oxygen concentration of 8% to 16.8% in rooms where there are no people is not effective .

A device for preventing re-ignition, providing filling the protected volume with an inerting mixture during ignition, and maintaining the oxygen level that prevents re-ignition using an inert gas generator (RF patent No. 2317835). A disadvantage of the known device that impedes the achievement of the following technical result is that inertization of the atmosphere in a closed room can lead to death of people from hypoxia.

There is a method of inertization and a device implementing it, in which, to prevent fire or explosion, the oxygen content in the protected volume is reduced to a basic level of inertization, which ensures the safe location of people, and when the oxygen content decreases below a safe level, fresh air is brought into the protected zone (patent for the invention RF 2372954). A disadvantage of the known device that impedes the achievement of the following technical result consists in the insufficient efficiency of inerting rooms in which people are absent.

To date, no means have been created that allow you to simultaneously vary the oxygen concentration in the mixture for inertization and depending on the presence of people in the protected volume to ensure maximum fire extinguishing while maintaining the safety of people inside the protected volumes and the integrity of the structures.

DISCLOSURE OF THE ESSENCE OF A USEFUL MODEL

In accordance with the above-described problems in the technical field and the disadvantages of the known solutions related to the inconsistency of the requirements for the efficiency and safety of fire extinguishing, the technical task of this utility model is to create a system that provides safe fire extinguishing when there are people in a confined space and effective fire fighting, in other cases.

The technical result of this utility model consists in solving the aforementioned technical problem, that is, in safe fire fighting in the presence of people in a confined space and in effective fire fighting in other cases.

These problems are solved due to the fact that the system of inertization of the atmosphere in a closed protected space contains:

management tools (SU),

ventilation means (CB) connected to the control system,

at least one oxygen concentration meter (ICC) connected to the control system and located in a protected space,

at least one fire detector (PI) connected to the control system and located in a protected space,

at least one pressure meter (ID) connected to the control system and placed in a protected space,

at least one human presence sensor (DPL) located in a protected space,

at least one position sensor (DP),

at least one controllable locking device (RAM),

at least one device for access control to the premises (UKDP), made with the possibility of transition between open and closed positions, and equipped with at least one DP and ultrasound

a node for supplying a mixture containing nitrogen and oxygen (UPAKS) connected to the control system and configured to controlledly change the oxygen concentration in the supplied mixture,

at least one controlled valve (UK) connected to the SU,

distribution pipeline (RT) connected to UPAKS and equipped with nozzles in communication with the protected space, and at least one UK, and

SUs are made with the possibility of determining fire, oxygen concentration, pressure, the position of UKDP and the presence of people by means of DCC, ID, PI and DP, respectively, and with the possibility of turning on / off the ultrasonic control, UK, UPAKS and SV and controlling the oxygen concentration of the mixture supplied by UPAKS, so that

in case of fire in the protected volume, they set the oxygen level in the mixture supplied by UPAKS in the range from 1 to 20%, include ultrasonic control, UPAKS and UK,

turn off UPAKS and CC when a predetermined critical pressure is reached for the time necessary for its normalization, and

by turning on / off the UK and UPAKS and / or SV, they maintain the minimum oxygen concentration suitable for breathing when there are people in the protected space, and in the absence of people maintain the oxygen concentration necessary to inertize the atmosphere in the protected space.

Hereinafter, the system, according to the present utility model, may be referred to as a "system".

The control system is used to collect data from all sensors of the system, analyze data and control the executive elements of the system. PI is used to detect fire in the protected space in case of its occurrence. CB is used to quickly increase the oxygen concentration in the protected space to the level suitable for breathing, if necessary, the access of people to the protected space. KIC are used to control the concentration of oxygen in the protected space. ID is used to control the level of pressure in the protected space within the limits safe for people and structures. DPL is used to determine the presence of people in the protected space, to issue a signal (CS) to maintain the oxygen concentration in the aisles acceptable for breathing in the event of the presence of people in the protected space. DP serves to control the position of the doors in the protected space, the issuance of a signal (SU) about the depressurization of the protected space. UZU serves to prevent unauthorized opening of doors to the protected space with a low (not suitable for breathing) oxygen concentration. УКДП serves to prevent unauthorized access of people to the protected space with a low (not suitable for breathing) oxygen concentration. UPAKS serves for the production of a mixture with a variable concentration of nitrogen content (80 ÷ 99%). The CC serves to enable / disable the supply of compressed air to the nitrogen generator, to enable / disable the supply of a mixture with a variable concentration of nitrogen content (80 ÷ 99%) into the protected space by command (CS). RT is used for transportation and supply of the prepared mixture with a variable concentration of nitrogen content (80 ÷ 99%) in the protected space.

In a particular embodiment, the UPAX comprises an air compressor (VK) having an input connected to the atmosphere outside the protected space and an output connected to an input of a compressed air dryer (OSV) having an output connected to an input of a nitrogen mixture generator (HAS) having the output connected to the input of the storage receiver (HP), the output of which is connected to the PT.

In a preferred embodiment, the HAS is selected from the group consisting of a membrane nitrogen generator and / or an adsorption nitrogen generator.

In yet another particular embodiment, the room access control device (DCD) is a hinged door or a sliding door.

In another particular embodiment, the system further comprises remote control means (CDS) located outside the protected volume and connected to the control system, and the control system is designed in such a way that, if there is a signal, the control system maintains a minimum oxygen concentration suitable for breathing by switching the CC on / off , UPAX and / or CB.

In a particular embodiment, the system further comprises light warning and / or information displays placed in said protected space and connected to the control system, and the control unit is configured to turn on / off said warning and / or information boards. The scoreboard may be turned on at a low and (or) inappropriate for breathing oxygen concentration.

In one particular embodiment, the system further comprises an emergency pressure relief valve (CASD) configured to open when a threshold pressure is reached in a protected space,

In yet another particular embodiment of the system, the fire detector comprises a heat, smoke, flame and / or gas sensor.

In a particular embodiment, the SWs comprise the supply ventilation (SCW) means connected to the control system, and the control system is configured to turn on and off the control system so that when the mixture is supplied to the protected volume or when a predetermined critical pressure is reached, it turns off the control system for the time required to normalize the pressure.

It should be understood that the above devices may be inherent in all or some of the features of the above particular and preferred embodiments, provided that they are compatible with each other, and such combinations of features are also included in the scope of this utility model.

For a better understanding of the ideas of this utility model, the following are illustrative drawings showing particular embodiments of the device, the presence, location, and proportions of the main structural elements. However, despite the fact that in this document a utility model is described with reference to the positions of the elements shown in the drawings, their features should not be attributed to the corresponding elements referred to in the text.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 shows a diagram of a system. Positions 1-21 indicate the following elements: compressor 1, air dryer 2, controlled valve 3, nitrogen generator 4, controls (controller) 5, storage receiver 6, exhaust gas 7, controlled valve 8, distribution pipe 9, presence sensor people 10, emergency pressure relief valve 11, oxygen concentration sensor 12, fire detector 13, pressure sensor 14, forced ventilation 15, exhaust ventilation 16, door position sensor 17, information panel 18, controlled locking device 19, button inclusion purge the protected space 20, the protected space (volume) 21.

IMPLEMENTATION OF A USEFUL MODEL

The following examples are given only to illustrate how to solve the technical problem. Nothing in this section of the description should be construed as limiting the scope of the claims. It should be clear that the average specialist familiar with the ideas of this utility model can use its main distinguishing features and make equivalent replacements with the achievement of the task and without deviating from the spirit and scope of this utility model.

The system of inertization of the atmosphere in a closed protected space, contains:

management tools (SU),

ventilation means (CB) connected to the control system,

at least one oxygen concentration meter (ICC) connected to the control system and located in a protected space,

at least one fire detector (PI) connected to the control system and located in a protected space,

at least one pressure meter (ID) connected to the control system and placed in a protected space,

at least one human presence sensor (DPL) located in a protected space,

at least one position sensor (DP),

at least one controllable locking device (RAM),

at least one device for access control to the premises (UKDP), made with the possibility of transition between open and closed positions, and equipped with at least one DP and ultrasound

a node for supplying a mixture containing nitrogen and oxygen (UPAKS) connected to the control system and configured to controlledly change the oxygen concentration in the supplied mixture,

at least one controlled valve (UK) connected to the SU,

distribution pipeline (RT) connected to UPAKS and equipped with nozzles in communication with the protected space, and at least one UK, and

SUs are made with the possibility of determining fire, oxygen concentration, pressure, the position of UKDP and the presence of people by means of DCC, ID, PI and DP, respectively, and with the possibility of turning on / off the ultrasonic control, UK, UPAKS and SV and controlling the oxygen concentration of the mixture supplied by UPAKS, so that

in case of fire in the protected volume, they set the oxygen level in the mixture supplied by UPAKS in the range from 1 to 20%, include ultrasonic control, UPAKS and UK,

turn off UPAKS and CC when a predetermined critical pressure is reached for the time necessary for its normalization, and

by turning on / off the UK and UPAKS and / or SV, they maintain the minimum oxygen concentration suitable for breathing when there are people in the protected space, and in the absence of people maintain the oxygen concentration necessary to inertize the atmosphere in the protected space.

The system operates as follows. The compressor compresses the atmospheric air and delivers it through an air dryer to the nitrogen mixture generator. The nitrogen mixture generator (GAS), depending on the given program, forms and feeds through the storage receiver into the protected space a mixture with a variable (from 80 to 99%) nitrogen concentration. Moreover, in the protected space by means of the oxygen sensor (s), continuous monitoring of the oxygen concentration is carried out. When the oxygen concentration reaches the specified parameters, the flow of nitrogen (mixture) is stopped. SU continuously monitors the oxygen concentration by means of DCC, and by controlling the CC and UPAX, it automatically maintains a given atmospheric composition. In the case when the atmosphere in the protected space is not suitable for breathing, that is, the oxygen concentration measured by DCC below a predetermined level, people's access to the protected space is blocked by turning on the ultrasound. The SU continuously monitors the presence or appearance of people in the protected space by means of DPS and, if there are people, the SU creates and maintains a breathable atmosphere in the protected space.

When the system is in standby mode (the protected space is closed, there are no people), the SU monitors the set oxygen concentration by means of DCC. With an increase in oxygen concentration, the SU switches off the AC, providing compressed air to the nitrogen generator (GAS), turns off the CC of the mixture store and delivers the mixture to the protected space until the oxygen concentration returns to the set limits, while the ID of the SU controls the pressure in the protected space. In case of increasing pressure in the protected space, the control system includes an exhaust ventilation system for normalization of pressure (the emergency pressure relief valve is an autonomous device and the control system is not controlled). After normalizing the pressure, the CB turns off. When the specified oxygen concentration is reached, the control system turns on the AC and turns off the mixture supply from the mixture accumulator.

If it is necessary for people to enter the protected space after receiving a signal, the system starts supplying a mixture with a suitable oxygen concentration for breathing into the protected space and turns on the supply and exhaust ventilation. When a concentration of oxygen suitable for human breathing is reached, the system unlocks access to the protected space by means of UKDP, DP, UZU. UZU opens access to the protected space, and the door position sensor DP informs the system about the position (opening / closing) of the door. DPL informs the system about the presence of people in the protected space. While people are in the protected space, the system delivers a breathable mixture to the protected space. After people exit the protected space (determined by means of the DPS and / or the signal of the system operator), the system goes into standby mode. Access to the protected space is blocked, the oxygen concentration decreases to predetermined limits.

In the event of a fire (triggering of PI) in the absence of people in the protected space (there is no signal from the DPS), the system switches to the mode of supplying a mixture with a high nitrogen content (99%) to the protected space. The supply and exhaust ventilation is turned off, the readings of the ID pressure meter sensor are ignored, and the overpressure is released through the emergency pressure relief valve.

In the event of a fire (triggering of PI) in the presence of people in the protected space (signal from the DPL), the system delivers a mixture with an oxygen concentration suitable for breathing into the protected space. Supply and exhaust ventilation is turned off, the pressure gauge (ID) sensor readings are ignored, the overpressure is released through the emergency pressure relief valve. After people exit the protected space (there is no DPS signal), the system delivers a mixture with a high nitrogen content (99%) into the protected space.

A mixture with a high nitrogen content is served until the fire is completely eliminated or until a cancel command (transfer to standby mode, access mode) is received from the system operator.

Changes and modifications of the above utility model, as well as additional applications of the principles laid down in its foundation, which are obvious to specialists in this field of technology, are also included in the scope of this utility model.

Claims (9)

1. The system of inertization of the atmosphere in a closed protected space, comprising: control means (CS), ventilation means (CB) connected to the CS, at least one oxygen concentration meter (ICC) connected to the CS, and located in the protected space, at least one fire detector (PI) connected to the control system, and located in the protected space, at least one pressure meter (ID) connected to the control system, and located in the protected space, at least one sensor human presence (DPL), at least one position sensor (DP) located in the space to be protected, at least one controllable locking device (UCS), at least one room access control device (UKPD) configured to transition between open and closed provisions and equipped with at least one DP and ultrasonic control unit, a node for supplying a mixture containing nitrogen and oxygen (UPAKS) connected to the control system and configured to control the change in the concentration of oxygen in the supplied mixture, at least one controlled valve (CC) , connected to the control system, distribution pipe (RT), connected to the UPAKS and equipped with nozzles in communication with the protected space, and at least one CC, characterized in that the control system is configured to determine fire, oxygen concentration, pressure, position УКДП and the presence of people by means of the ICC, ID, ПИ and ДП, respectively, and with the possibility of turning on / off the УЗУ, УК, UPАКС and СВ and controlling the oxygen concentration of the mixture supplied by UPAKS, so that in a fire in a protected volume they set the oxygen level in the mixture supplied by UPAKS is varied in the range from 1 to 20%, include ultrasonic control, UPAKS and UK, turn off UPAKS and UK when a predetermined critical pressure is reached for the time required for its normalization, and by turning on / off the UK and UPAKS and / or CB, maintain a minimum oxygen concentration suitable for breathing when there are people in the protected space, and in the absence of people maintain the oxygen concentration necessary to inertize the atmosphere in the protected space. 2. The system according to claim 1, characterized in that in it the UPAX contains an air compressor (VK) having an input connected to the atmosphere outside the protected space, and an output connected to the input of a compressed air dryer (OSV) having an output, connected to the input of the nitrogen mixture generator (HAS), having an output connected to the input of the storage receiver (HP), the output of which is connected to a distribution pipe (RT). 3. The system according to claim 2, characterized in that the GAS in it is selected from the group consisting of a membrane nitrogen generator and / or an adsorption nitrogen generator. 4. The system according to claim 1, characterized in that in it at least one device for access control to the premises (UKDP) is a swing door or a sliding door. 5. The system according to claim 1, characterized in that it further comprises means of remote control (CDS) located outside the protected volume and connected to the control system, and the control system is designed in such a way that, if there is a signal, the control system maintains a minimum oxygen concentration suitable for breathing by turning on / off the UK, UPAKS and / or SV. 6. The system according to claim 1, characterized in that it additionally contains a warning light and / or information display located in the aforementioned protected space and connected to the control system, and the control unit is configured to turn on / off the warning and / or information board in case of fire. 7. The system according to claim 1, characterized in that it further comprises an emergency pressure relief valve (CASD), configured to open when the threshold pressure in the protected space is reached. 8. The system according to claim 1, characterized in that the fire detector contains a thermal, smoke, flame and / or gas sensor. 9. The system according to claim 1, characterized in that in it the SVs contain the means of fresh air ventilation (SPV) connected to the control system, and the control system is configured to turn on and off the ventilation system so that when the mixture is supplied to the protected volume or when a predetermined critical pressure is reached, it turns off the SPW for the time necessary to normalize the pressure.