RU2135240C1 - Computer-aided fire-protection control system - Google Patents

Abstract

FIELD: fire protection systems. SUBSTANCE: system has fire detectors, environment condition sensors, weather condition sensors, process equipment condition sensors, fire-fighting equipment condition sensors, personnel and door locks location monitors, logic unit, control unit, operator's console, alarm, emergency warning and evacuation control devices, devices for starting emergency emission confining facilities, devices for starting fire-fighting equipment, devices for starting cooling and thermal protection facilities, devices for automatic turning-off and change-over of circuit-opening and switching devices, door locking devices, personnel action check-up unit, and fire-fighting monitoring unit. EFFECT: enlarged functional capabilities, improved safety of personnel, provision for taking adequate measures to cope with emergency situation. 2 cl, 2 dwg

Description

 The invention relates to fire fighting equipment, in particular to fire safety systems, designed to prevent the possibility of fires and explosions and to ensure high-quality fire fighting in the event of an emergency. The invention can be used in industry, especially in enterprises with potentially explosive and fire hazardous continuous processes, for example, in the oil refining, petrochemical and chemical industries.

 A known fire safety system [USSR Author's Certificate N 797706, MKI A 62 C 37/10, 1979], containing fire detectors connected to signal converters, environmental parameters sensors, process equipment parameters sensors, process parameters sensors, false positive detection unit, logic unit, control unit, computing device, group alarm unit, operator panel, alarm devices, fire extinguishing system start-up devices, avar devices switching off and switching devices and switching, an automatic control unit for the parameters of the technological process and technological equipment.

 Obtaining the required technical result is hampered by the limited functionality of the above system, which are not able to eliminate all possible dangerous factors that arise in modern enterprises.

 Closest to the claimed invention is a well-known automated fire protection control system [USSR Patent N 1788902, MKI A 62 C 37/10, 1993], comprising fire detectors connected to a signal converter, environmental sensors, meteorological sensors, process sensors equipment, process parameter sensors, technical condition sensors of fire extinguishing installations, connected through signal converters to the corresponding m inputs of the computing device, a false alarm detection unit, the output of which is connected to the operator’s console, a logical unit, a control unit, alarm devices connected through the group alarm unit to the first output of the logical unit, emergency warning and evacuation control devices connected through the emergency warning unit to the second output of the logical unit, the trigger device for localizing accidental emissions connected to the first output of the control unit, the trigger device fire extinguishing panels connected to the second output of the control unit, cooling and thermal protection start-up devices, connected to the third output of the control unit, emergency shutdown and switching devices and switching devices connected to the fourth output of the control unit, while the first output of the computing device is connected to the first the input of the logical unit, the second - to the first input of the control unit, the third is connected to the operator console, the fourth - to the input of the automatic control unit technological process and technological equipment, and the fifth is connected to the input of the unit for automatically turning on the backup devices of fire extinguishing and warning alarms, the first output of the signal converter from fire detectors is connected to the logic unit, the second to the false alarm detection unit, and the third to the control unit, fifth the output of the control unit is connected to the input of the false alarm detection unit, the output of the logical unit is connected to the input of the operator panel.

 Obtaining the required technical result is hampered by the limited functionality of the above system, which is not able to provide maximum safety for personnel in case of an emergency, as well as to quickly control the quality of fire fighting.

 The task to be solved by the claimed invention is directed is to ensure maximum personnel safety and ensure that effective measures are taken during emergency response due to the operational reflection of fire extinguishing quality control.

 The technical result in the implementation of the claimed invention is expressed in expanding the functionality of the system.

 To achieve the above technical result, an automated fire protection control system comprising fire detectors connected to a signal converter, environmental sensors, meteorological parameter sensors, process equipment parameter sensors, process parameter sensors, technical condition sensors of fire extinguishing installations connected via signal converters to the corresponding inputs of the computing device to detect false alarms, the output of which is connected to the operator’s console, a logical unit, a control unit, alarm devices connected through the group alarm unit to the first output of the logical unit, emergency warning and evacuation control devices connected through the emergency notification unit to the second output of the logical unit , start-up devices for means of localizing accidental emissions connected to the first output of the control unit, start-up devices for fire extinguishing installations, connected to the second output of the control unit, the starting device for cooling and thermal protection devices connected to the third output of the control unit, the emergency shutdown and switching devices and switching devices connected to the fourth output of the control unit, while the first output of the computing device is connected to the first input of the logical unit, the second - to the first input of the control unit, the third is connected to the operator console, the fourth - to the input of the unit for automatic control of process parameters and equipment, and the fifth is connected to the input of the unit for automatically switching on the backup devices of fire extinguishing and warning alarms, the first output of the signal converter from fire detectors is connected to the logical unit, the second to the false alarm detection unit, and the third to the control unit, the fifth output of the control unit connected to the input of the false alarm detection unit, the output of the logical unit is connected to the input of the operator console, complemented by sensors for monitoring the location of personnel and door locks connected via a signal converter to a computing device, door blocking devices connected to the sixth output of the computing device, a personnel action control unit and a fire extinguishing quality control unit connected to an operator console, the second outputs of signal converters from process equipment parameter sensors , sensors of process parameters and sensors for monitoring the location of personnel and door locks are connected to to the input inputs of the personnel action control unit, the second output of the signal converter from fire detectors is connected to the first input of the fire extinguishing quality control unit, to the second input of which the second output of the signal converter from the sensors of the technical state of fire extinguishing installations is connected, to the third - the output of the personnel action control unit, to the fourth - the operator console, to the fifth - the output of the signal converter from the environmental sensors, the first output of the extinguishing quality control unit Ożarów connected to a computing device, the second output suppression unit QC fire - to the console operator. In the particular case of the system execution, the computing device can be made up of a signal receiving unit, a safety criterion calculation unit, an emergency analysis unit, and an emergency development prediction unit.

 Introduction to the system of sensors for monitoring the presence of personnel and door locks and door locking devices allows you to accurately monitor the presence of personnel at the time of the accident and enable fire extinguishing installations, taking into account the factor of people in the area of these installations, as well as lock the doors to prevent personnel from entering the accident zone, which ultimately allows to ensure the greatest safety of personnel. The introduction of a personnel control unit and a fire extinguishing quality control unit into the system provides a timely display of the operational situation on the operator console, and also allows you to take into account the correctness of personnel actions in predicting the development of an emergency, and as a result, take the most effective measures in responding to an accident.

 In FIG. 1 shows a block diagram of an automated fire protection control system, FIG. 2 is a block diagram of a computing device.

 The automated fire protection control system includes fire detectors 1 connected to a signal converter 8, environmental sensors 2, meteorological sensors 3, process equipment sensors 4, process parameters sensors 5, technical condition sensors for fire extinguishing installations 6, location monitoring sensors personnel and door locks 7 connected through appropriate signal converters 9-14 to the corresponding input am of the computing device 18, the false alarm detection unit 15, the output of which is connected to the operator console 21, the logic unit 16, the control unit 17, the alarm devices 22 connected through the group alarm unit 19 to the first output of the logical unit 16, the emergency warning and control device evacuation 23, connected through the emergency block 20 to the second output of the logical block 16, the trigger device for localizing emergency emissions 24, connected to the first output of the control unit 17, device start-up properties of fire extinguishing installations 25, connected to the second output of the control unit 17, devices for starting the cooling and thermal protection devices 26, connected to the third output of the control unit 17, emergency shutdown and switching devices and switching 27, connected to the fourth output of the control unit 17, devices door locks 30, connected to the sixth output of the computing device 18, a unit for controlling the actions of personnel 31 and a unit for controlling the quality of extinguishing fire 32, connected to the operator panel. In this case, the first output of the computing device 18 is connected to the first input of the logical unit 16, the second is connected to the first input of the control unit 17, the third is connected to the operator console 21, the fourth is connected to the input of the automatic control unit of the parameters of the technological process and technological equipment 28, and the fifth is connected to the input of the unit for automatically turning on backup devices of fire extinguishing and warning alarm 29, the first output of the signal converter from fire detectors 8 is connected to a logical block 16, the second to the false alarm detection unit 15, and the third to the control unit 17, the fifth output of the control unit 17 is connected to the input of the false alarm detection unit 15, the output of the logical block 16 is connected to the input of the operator console 21. The second outputs of the signal converters from sensors of parameters of technological equipment 4-11, sensors of parameters of technological process 5-12 and sensors for monitoring the location of personnel and door locks 7-14 are connected to the corresponding inputs of the control unit for personnel actions 31. Second the first output of the signal converter from fire detectors 8 is connected to the first input of the fire extinguishing quality control unit 32, the second input of which is connected to the second output of the signal converter from the sensors of the technical parameters of fire extinguishing systems 6 - 13, to the third - the output of the personnel actions control unit, to the fourth - operator’s console, to the fifth - the output of the signal converter from the sensors of environmental parameters 2-9, the first output of the fire extinguishing quality control unit 32 is connected to the computing device 1 8, the second output of the fire extinguishing quality control unit 32 - to the operator console 21.

 Computing device 18 consists of a signal receiving unit 33, a safety criterion calculation unit 34, an emergency analysis unit 35, and an emergency development prediction unit 36.

 The system operates as follows. Data on environmental parameters, meteorological parameters, data on the parameters of technological equipment and process parameters, data on the location of personnel, data on the status of fire extinguishing installations are received from sensors 2-7 through the corresponding signal converters 9-14 to the input of the signal receiving unit 33 of the computing device 18. In the signal receiving unit, the signals are processed and converted for transmission to the safety criterion calculation unit 34, where, in accordance with the mathematical mode In order to describe the object from the point of view of explosion and fire safety, a comprehensive safety indicator is calculated, depending on the value of which a signal is generated that is transmitted to the input of the emergency analysis unit 35. In the emergency analysis unit 35, the current safety indicator is compared with the standard and the previous value to determine rate of change. The time is predicted by the rate of change of the complex safety indicator, after which, in the absence of an external control action, this indicator can reach the maximum permissible value at which an emergency occurs at the facility. Then, parameters are determined that contribute to increasing the speed of approaching the comprehensive safety indicator to the maximum permissible limits, signals are generated for the correction of these parameters, which from the output of the emergency analysis unit 35 go to the input of the automatic control unit for the parameters of the technological process and technological equipment 28, as well as to the input the unit for automatically activating the backup of fire extinguishing and warning systems 29. Signals are proportional to e expected time of reaching a complex refractive security maximum allowable value, the output unit 35 are input to the operator console 21 for visual evaluation of the current situation in the protection object.

 When a complex indicator reaches the normative maximum permissible value, from the output of block 35 to the input of the control unit 17 and to the input of the logical block 16, signals are identified that identify the parameters that cause the occurrence of an explosive and fire hazard situation. In the process of analyzing these signals, the control unit 17 determines the devices and communications that must be partially or completely disconnected or blocked to eliminate the risk of fire (explosion), and signals are generated to actuate the emergency shutdown and switching devices and communications 27.

 From another output of the control unit 17, a signal is input to the input of the false alarm detection unit 15 operating in the "AND" mode. In the logical block 15, the zone in which an explosive and fire hazard situation has occurred is determined and signals are generated to turn on the indication on the operator panel 21, as well as signals received at the input of the group alarm block 19, which includes signaling devices 22 in the accident zone.

 If the integrated safety indicator exceeds the maximum permissible value in the emergency analysis unit, signals corresponding to the accident mode are generated. Signals of this type are sent to the emergency forecasting unit 36, in which the program determines the sizes of the zones of hazardous concentrations of combined-cycle gases and calculates the movement of explosive atmospheres over the territory of the protection object, taking into account the signals from the signal receiving unit 33. According to the calculation method implemented in programmable block 36, the calculation of forecasts of the development of the emergency is made taking into account factors such as environmental parameters, meteorological parameters, technical parameters of the equipment and process. Signals reflecting the results of the calculation are sent to the emergency analysis unit 34 and to the operator console 21. In the emergency analysis unit 34 of the computing device 18, the received signals are converted into control signals that are input to the control unit 17 and the input of the logical unit 16. According to these signals or by command from the operator’s console 21, the control unit 17 includes devices for launching means for localizing emergency emissions, water and gas-vapor barriers 24. A signal on the reliability of starting means 24 is received and the operator console 21 and includes a light indication.

 Logic block 16 determines the probable boundaries of the hazardous area on the territory of the object of protection and generates signals to turn on the light indication, highlighting the danger zone on the operator panel 21, and signals arriving at emergency warning unit 20, which includes emergency warning and evacuation control devices 23, in that zone where there is a danger of an accident. The data obtained in the computing device on the forecasts of the development of the emergency (the size of the explosive cloud, direction, speed and time of its distribution) are displayed on the display (or on the printing device) of the operator panel 21 for a visual assessment of the situation and the decision by the operator on the need to evacuate the population nearby the object of protection of residential quarters and maintenance personnel of neighboring industrial facilities.

 When the fire detectors 1 are triggered, the signals through the signal converter 8 are fed to the input of the control unit 17, the input of the logical unit 16, the input of the false alarm detection unit 15 and the personnel actions control unit 31. In this case, the logical unit 16 determines the zone in which the fire occurred and generates a signal to turn on the indication for displaying on the operator’s console 21 of the fire zone, and a signal to the group alarm block 19, which includes alarm devices 22 on the operator’s console and directly in the area where fire.

 The control unit 17 generates a signal that acts on the start-up devices of the fire extinguishing installations 25, and at the output of the false alarm detection unit 15, in the presence of a signal from the control unit 17, a signal is transmitted to the operator console 21 and confirms the truth of the information received from the fire detectors 1. When when this signal is received automatically or by command from the operator’s console 21, the control unit 17 includes devices for starting the cooling means and thermal protection 26 directly in the area where the fire is. In the absence of such a signal at the output of the false alarm detection unit 15, the operator of the remote control 21 gives the command to the control unit 17 to turn off the fire extinguishing installations 25.

 Data on the location of the personnel and door locks from the sensor 7, data on the parameters of technological processes from the sensors 5 and data on the status of the technological equipment 4 through the corresponding converters 11, 12, 14 are received at the inputs of the personnel action control unit, which, by command from the operator console 21, in accordance with the program, which provides for determining the actions of personnel in the event of an accident, affecting the parameters of the process and the state of maintenance (in case of an accident, it mainly uses manual control of equipment and processes), they compare the parameters of technological processes and the state of technological equipment with the correct regulation of personnel actions in accordance with its location at the time of the accident. Based on the results of this comparison, a signal is generated that is transmitted to the input of the operator console 21 and to the input of the fire extinguishing quality control unit 32.

 The fire extinguishing quality control unit 32 receives signals about the state of the fire extinguishing installations from the sensors 6 through the signal converter 13, data from the fire detectors 1 through the signal converter 8, data on the correct actions of the personnel from block 31 and environmental data from the sensors 2 through the converter signals 9. According to the program implemented in the fire extinguishing quality control unit 32, an analysis is made of the change in the state of the environment in the accident area depending on the operation of the fire extinguishing installations arrangements for the protection and localization of accidental releases, personnel actions, as well as other measures taken to contain the accident. The signals generated on the basis of an intermediate analysis are transmitted to the operator console 21 and to the computing device 18 to the signal receiving unit 33. As a result, in accordance with the calculation methodology implemented in the programmable unit 36, the forecasts of the development of the emergency are calculated taking into account the additional factors such as the correctness of personnel actions and the level of fire extinguishing quality. Signals reflecting the results of the calculation are sent to the emergency analysis unit 34 and to the operator console 21.

 The proposed system allows to significantly increase the level of security of the object of protection and to ensure the adoption of the right decisions in the liquidation of an emergency by taking into account the correctness of the actions of personnel and operational reflection of the quality control of fire fighting.

Claims (2)

 1. An automated fire protection control system, comprising fire detectors connected to a signal converter, environmental sensors, meteorological sensors, process equipment sensors, process sensors, technical condition sensors of fire extinguishing systems, connected through signal converters to the corresponding inputs computing device, false positive detection unit, the output of which is under accessed to the operator console, a logical unit, a control unit, alarm devices connected through the group alarm unit to the first output of the logical unit, emergency warning and evacuation control devices connected through the emergency notification unit to the second output of the logical unit, trigger device for localizing emergency emissions connected to the first output of the control unit, devices for starting fire extinguishing installations, connected to the second output of the control unit, devices for starting medium cooling and thermal protection TV connected to the third output of the control unit, emergency shutdown and switching devices and switching devices connected to the fourth output of the control unit, while the first output of the computing device is connected to the first input of the logic unit, the second to the first input of the control unit, the third is connected to the operator’s console, the fourth is connected to the input of the automatic control unit for the parameters of the technological process and technological equipment, and the fifth is connected to the input of unit a the automatic activation of fire extinguishing and warning alarm backup devices, the first output of the signal converter from fire detectors is connected to the logic unit, the second to the false alarm detection unit, and the third to the control unit, the fifth output of the control unit is connected to the input of the false alarm detection unit, output the logical unit is connected to the input of the operator’s console, characterized in that it additionally contains sensors for monitoring the location of personnel and door locks, according to connected via a signal converter to a computing device, door blocking devices connected to the sixth output of the computing device, a personnel action control unit and a fire extinguishing quality control unit connected to an operator console, the second outputs of signal converters from process equipment parameters sensors, process parameters sensors and sensors for monitoring the location of personnel and door locks are connected to the corresponding inputs of the control unit for personnel, the second output of the signal converter from fire detectors is connected to the first input of the fire extinguishing quality control unit, the second input of which is connected to the second output of the signal converter from the sensors of the technical state of fire extinguishing installations, the third is the output of the personnel action control unit, and the fourth is the remote operator, to the fifth - the output of the signal converter from the sensors of environmental parameters, the first output of the fire extinguishing quality control unit is connected to the computer device, the second output suppression of the quality control unit of fire - to the attendant console.  2. The automated fire protection control system according to claim 1, characterized in that the computing device consists of a signal receiving unit, a safety criterion calculation unit, an emergency analysis unit and an emergency development prediction unit.

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