RU132072U1 - AUTOMATED FIRE PROTECTION SYSTEM - Google Patents

Abstract

1. An automated fire protection system containing a digital video surveillance module, the output of which is connected to the first input of the operator’s workstation, the output of which is connected to the first input of the fire fighting module and the first input of the fire warning and evacuation control module, fire alarm module, the first output of which connected to the first input of the controller, the first output of which is connected to the second input of the operator’s workstation, characterized in that in it given a thermal imager, a module for detecting a fire hazard situation and a fire prevention module, the first output of the thermal imager is connected to the third input of the operator’s workstation, the output of which is connected to the first input of the fire prevention module, the second output of the thermal imager is connected to the second input of the controller, the second output of which is connected to the second input fire prevention module, the output of the fire hazard detection module is connected to the third input of the controller, the second output of the fire alarm module is The key to the second input module firefighting and second input module warning people about the fire and evakuatsiey.2 management. The automated fire protection system according to claim 1, characterized in that the prevention module comprises an electric control and control unit, high pressure pumps, a block of shut-off elements, a water spray unit and a signaling unit, the first input of the electric control and control unit is the first input of the prevention module fire, the second input of the control unit electric

Description

Automated fire protection systems (ASPA) are known from the prior art, which are a set of technical means designed to protect people and property from the effects of dangerous fire factors and (or) limit the effects of dangerous fire factors on an object [1]. Modern ASPAs can function independently or as part of integrated security systems [2].

For example, the system [3] is known. To increase the effectiveness of fire protection, it uses visual monitoring of the state of the object by integrating fire detection tools with a video surveillance system. Modern CCTV systems as part of the ASPA can also be equipped with software modules for recognizing situations, in particular, signs of an accident leading to a fire. At the same time, the possibilities of video surveillance are limited, in particular, due to the difficulty of practical implementation of the pairing of the review of cameras and detection zones of fire detectors, as well as the inability to detect areas of the object with high temperature, which can be ignition sources.

Partially, the shortcomings [3] were eliminated in ASPA [4], which is the closest to the claimed system. In [4], the efficiency of its operation was significantly increased due to earlier and more reliable fire detection, as well as its rapid localization and extinguishing due to the introduction of fire detectors, coupled with video cameras, an autonomous fire extinguishing module, a water fire extinguishing module, including a foam extinguishing installation, an irrigation installation water curtain control unit.

The block diagram of the device of the prototype [4] is shown in figure 1.

The system contains a digital video surveillance module 1, a monitoring and control unit 2, a fire alarm module 3, fire flame detectors 4 with an integrated video camera, a controller 5, a power and control module 6, an automated workstation for an operator 7, an autonomous fire extinguishing module 8, a water fire extinguishing module 9 , fire warning and evacuation management module 10.

Digital video surveillance module 1, controller 5, automated workstation of the operator 7, module for alerting people about fire and evacuation control 10, the third input of the water fire extinguishing module 9 are interconnected by a common channel for receiving and transmitting information, the output of the fire alarm module 2 is connected to the first input of the controller 5, the output of the fire detectors of flame 4 with an integrated video camera is connected to the second input of the controller 5, the output of the autonomous fire extinguishing module 8 is connected to the third input of the controller 5, the output of the Control and control 2 is connected to the fourth input of controller 5, the first and second outputs of controller 5 are connected to the corresponding first and second inputs of the power and control module 6, the first and second outputs of which are connected to the corresponding first and second inputs of the water extinguishing module 9.

The disadvantage of the system [4] is that the duration of the visual analysis of the situation may be unacceptably long for a number of industrial facilities related, for example, to the oil refining process. In them, a fire hazard situation that may arise as a result of a pre-emergency situation or an accident at a technological installation is characterized by the rapid appearance of a combustible load in the event of leakage of combustible gases (GH), vapors of a flammable liquid (LVL), and ignition sources in the form of overheated plant elements.

Thus, an accident can lead to a fire and / or explosion in a short time. The inability to detect a fire hazard situation and take measures to eliminate it or stop further development with the transition to a fire (explosion) reduces the effectiveness of the prototype device [4].

The objective of this utility model is to increase the efficiency of an automated fire protection system.

The technical result achieved by the implementation of the claimed utility model is to increase the efficiency of the system by introducing a thermal imager, a module for detecting a fire hazard and a module for preventing fire in case of emergency or emergency situations.

The specified technical problem is solved due to the fact that the known prototype device [4] contains a digital video surveillance module, the output of which is connected to the first input of the operator’s workstation, the output of which is connected to the first input of the fire fighting module and the first input of the fire warning module and evacuation control, a fire alarm module, the first output of which is connected to the first input of the controller, the first output of which is connected to the second input of the workstation of the torus, a thermal imager, a fire hazard detection module and a fire prevention module are introduced, the first output of the thermal imager is connected to the third input of the operator’s workstation, the output of which is connected to the first input of the fire prevention module, the second output of the thermal imager is connected to the second input of the controller, the second output of which is connected to the second input of the fire prevention module, the output of the fire hazard detection module is connected to the third input of the controller, the second output of the fire signal module The fire alarm is connected to the second input of the fire extinguishing module and the second input of the fire warning and evacuation control module.

Figure 2 shows a block diagram of the inventive automated fire protection system.

The system contains a digital video surveillance module 1, a thermal imager 2, a fire hazard detection module 3, an operator workstation 4, a controller 5, a fire alarm module 6, a fire extinguishing module 7, a fire warning and evacuation control module 8, and a fire prevention module 9.

The output of the digital video surveillance module 1 is connected to the first input of the operator’s workstation 4, the output of which is connected to the corresponding first inputs of the fire extinguishing module 7, the fire warning and evacuation control module 8 and the fire prevention module 9, the first output of the fire alarm module 6 is connected to the second the entrance of the operator’s workstation 4, the second output of the fire alarm module 6 is connected to the corresponding second inputs of the fire extinguishing module 7, the people warning module about the fire and evacuation control 8, the first output of the thermal imager 2 is connected to the third input of the operator’s workstation 4, the second output of the thermal imager 2 is connected to the second input of the controller 5, the first output of which is connected to the second input of the operator’s workstation 4, and the second output of the controller 5 connected to the second input of the fire prevention module 9, the output of the fire hazard detection module 3 is connected to the third input of the controller 5.

The module for detecting a fire hazard situation 3 contains thermal sensors 10, sensors of the gas analyzer 11 and a power supply and control unit 12.

The automated workstation of the operator 4 contains monitors 13-15 and a computer server 16.

The fire alarm module 6 comprises fire detectors 17 and a fire control device 18.

The fire prevention module 9 comprises an electric control and control unit 19, high pressure pumps 20, a block of shut-off elements 21, a block of water atomizers 22, and a block of signaling devices 23.

In the module for detecting a fire hazard situation 3, thermal sensors 10 are connected to the first input of the power supply and control unit 12, the sensors of the gas analyzer 11 are connected to the second input of the power supply and control unit 12, the output of which is the output of the module for detecting a fire hazard situation 3.

In the automated workstation of operator 4, the first input of the server computer 16 is connected to the monitor 13 and is the first input of the automated workstation of the operator 4, the second input of the computer server 16 is connected to the monitor 14 and is the third input of the automated workstation of the operator 4, the third input of the computer server 16 is connected to the monitor 15, the fourth input of the server computer 16 is the second input of the operator’s workstation 4, the output of the server computer 16 is the output of the automated work operator of 4 seats.

In the fire alarm module 6, the fire detectors 17 are connected to the fire control device 18, the first information output of which is the first output of the fire alarm module 6, and the second control output is the second output of the fire alarm module 6.

In the fire prevention module 9, the first input of the electric control and control unit 19 is the first input of the fire prevention module 9, the second input of the electric control and control unit 19 is the second input of the fire prevention module 9, the first output of the electric control and control unit 19 is connected to the first input of the unit locking elements 21, the second output of the control unit 19 is connected to the input of the high pressure pumps 20, the output of which is connected to the second input of the block of locking elements 21 the first output of which is connected to the block of water sprayers 22, the second output of the block of locking elements 21 is connected to the input of the block of signaling devices 23, the output of which is connected to the third input of the control and electric control unit 19.

To achieve a technical result when implementing a utility model, the following options for the technical implementation of individual blocks can be used.

Digital video surveillance module 1, controller 5, automated workstation of operator 7, module for alerting people about fire and evacuation control 8, fire extinguishing module 10 can be performed using well-known technical solutions identical to the prototype system [3].

The fire alarm module 6 includes commercially available fire detectors of various types, for example, smoke, heat, combined [5], as well as a fire control device, for example, Potok-3N, designed to organize a fire alarm and alert and fire extinguishing [6].

The module for detecting a fire hazard situation 3 can be performed, for example, using thermal sensors of the company NPF Agrostroy, as well as gas analysis sensors Gazotest-3001 [7], combined by the control unit of the company Agrostroy [8].

The data transmission channel used for communication between the modules can use a standard data exchange protocol, for example, RS485.

The system works as follows:

Under normal conditions, the monitors 13-15 of the operator’s automated workstation 4 display the state of the object: images of the object’s sections in the visible spectrum in the zone of operation of the video cameras of the digital video surveillance module 1, in the infrared region of the spectrum - in the zone of operation of the cameras 2, as well as information from sensors 10, 11 of the module 3 detection of a fire hazard.

When signs of a fire hazard occurring at the facility, characterized by the presence of gas leaks, the appearance of flammable vapor and / or high-temperature ignition sources, they are detected by the operator using signals displayed on the monitors of the operator’s workstation 4.

The occurrence of GH leaks can be detected when they leak from the technological apparatus using the sensors of the gas analyzer 11. In this case, when the concentration of the detected GH exceeds the established limits, the power supply and control unit 12 generates at its output a signal to the input of the controller 5, which transfers information to the first output the operator’s computer for subsequent display on the monitor 15, and on the second output generates a control command to enable the fire prevention module 9.

Overheated places of the technological apparatus are detected with the help of a thermal imager 2, as well as with the help of thermal sensors 10 installed in inaccessible for viewing cameras of a thermal imager 2. When the temperature exceeds a set threshold value, signals from the second output of the thermal imager 2 or from the output of the power supply and control unit 12 are fed the inputs of the controller 5, which on the first output transmits information to the operator’s computer for subsequent display on the monitor 15, and forms a control command at the second output to include fire prevention module 9.

Using the digital video surveillance module 1 and the thermal imager 2, the operator himself can detect a fire hazardous emergency at its early stage by characteristic signs. For example, a GG leak or a significant overheating of equipment can be detected by thermal contrast on the monitor 14 of the thermal imager 2. In this case, the operator using the computer 16 generates a control command to turn on the fire prevention module 9.

The fire prevention module 9 operates as follows. In the fire prevention module 9, the electric control and control unit 19 is connected to the high pressure pumps 20 and the block of shut-off elements 21 by a power cable. High pressure pumps 20 are connected to the water supply system of the facility. The pumps are connected to a block of shutoff valves 21 connected to the block of water sprayers 22 by means of steel pipes. The block of water sprayers 22 is a set of distribution pipelines equipped with nozzles for producing finely atomized water.

Upon receipt of a signal from the controller 5 or the operator’s automated workstation 16 to start, the electric control and control unit 19 generates control pulses to the block of valves 21 according to the direction of water supply, and also turns on high pressure pumps 20. The pumps supply pressure water through a piping system and a block of shutoff valves 21 to a block of water sprayers 22, forming a stream of finely atomized water to cool heated surfaces and to prevent possible fires. The block of alarm devices 23 when starting the fire prevention module 9 registers a change in pressure, which is signaled to the control and control panel 19, which provides control of the start and operation of the fire prevention module 9.

When signs of fire appear on the object, they are detected by the respective detectors 17 of the fire alarm module 6, and information about the fire using the controller 5 and computer 16 is displayed on the monitor 15 of the operator’s automated workstation 4. The operator has the ability to verify the correctness of the generated fire notification by viewing the video image on the monitor 13.

In the case of confirmation of the occurrence of a fire, the operator generates control commands to turn on the fire extinguishing means of the fire extinguishing module 7 and the warning and evacuation means of module 8.

In established cases, these modules can be switched on automatically by signals from the second control output of the fire control device 18 of the fire alarm unit 6.

Thus, the proposed automated system completely solves the problem of ensuring the fire safety of an industrial facility. This ensures increased efficiency of its operation by detecting and eliminating a fire hazard in the event of emergency or emergency situations at the facility, achieved by introducing a thermal imager, a fire hazard detection module and a fire prevention module into the automated fire protection system.

INFORMATION SOURCES:

1. The law of the Russian Federation of July 22, 2008 No. 123-ФЗ "Technical regulation on fire safety requirements".

2. GOST R53704-2009. Security systems integrated and integrated. General technical requirements. - M .: Standartinform-2009.

3. RF patent for utility model No. 105052 IPC G0B 13/00. from. 02/10/2011, publ. 05/27/2011. Bull. No. 15.

4. RF patent for utility model No. 116670 IPC G0B 13/00 of 02/07/2012, publ. May 27, 2012 Byul. No. 15.

5. Kiryukhina T.G., Members A.N. Technical means of security. Part 1. Security and fire alarm systems. Video control systems. Integrated Systems. Access Control and Management Systems - M .: NOU "Takir", 2002 - 215 p.

6. Fire control device "Potok-3N" Operation manual АЦДР.425533.003 РЭ.

7. Gas analyzer-signaling device "Gazotest-3001/3003" Passport MEKV. 413210.001 Substation.

8. A set of hardware "Agrostroy", http://www.cataloxy.ru/firms/moscow/www.agrostroy.ru.

9. Thermal imager "FLIR-a310f" www.pergam.ru/catalog/thermal imagers / fire service.

10. Fire Prevention Module www.temasistemi.com/aquatech/catalog aquatech.php.

Claims (2)

1. An automated fire protection system containing a digital video surveillance module, the output of which is connected to the first input of the operator’s workstation, the output of which is connected to the first input of the fire fighting module and the first input of the fire warning and evacuation control module, fire alarm module, the first output of which connected to the first input of the controller, the first output of which is connected to the second input of the operator’s workstation, characterized in that in it given a thermal imager, a module for detecting a fire hazard situation and a fire prevention module, the first output of the thermal imager is connected to the third input of the operator’s workstation, the output of which is connected to the first input of the fire prevention module, the second output of the thermal imager is connected to the second input of the controller, the second output of which is connected to the second input fire prevention module, the output of the fire hazard detection module is connected to the third input of the controller, the second output of the fire alarm module is The key to the second input module firefighting and second input module warning people about the fire and evacuation management. 2. The automated fire protection system according to claim 1, characterized in that the prevention module includes an electric control and control unit, high pressure pumps, a block of shut-off elements, a water spray unit and a signaling unit, the first input of the electric control and control unit is the first input fire prevention module, the second input of the electric control and control unit is the second input of the fire prevention module, the first output of the electric control and control unit is connected to the first input of the block of locking elements, the second output of the control and electric control unit is connected to the input of the high pressure pumps, the output of which is connected to the second input of the block of locking elements, the first output of which is connected to the block of water sprayers, the second output of the block of locking elements is connected to the input of the block signal devices, the output of which is connected to the third input of the control unit and electric.

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