RU2603827C1 - Method of emergency situation development prediction at explosive facility - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to chemical and general machine building, in particular to safety systems, preventing development of emergency situation. Disclosed is method of emergency development prediction during accident on explosive facility, consisting in, that using monitoring system with obtained information on hazardous area processing for making decision on emergency situation preventing. Explosive facility mockup is installed in test box, and along its internal and external perimeters video cameras are arranged for video monitoring of emergency situation development process during accident on explosive facility, which is simulated by mounting explosive splintery element with explosion trigger in mockup. Video cameras are made in explosion-proof version, and outputs from video cameras are connected through spacers inner cavity to unit, by means of which the processes of change of parameters in the model are recorded and registered. Registering changes of process parameters in explosive facility mockup recorded waveform processes by means of system analyzers, and in mockup ceiling part opening is made, which is closed with explosion-proof element, installed freely on three resilient pins, one end of each of which is rigidly fixed in mockup ceiling, and at second horizontal bar is fixed between explosive fragmentation element and opening. Installing three-dimensional pressure sensor in explosion-proof design, which output is connected to recording and registering equipment unit input, and at both sides of pressure transmitter temperature and humidity sensors are installed, controlling temperature and humidity conditions in mockup, which outputs are also connected to recording and registering equipment unit input, and mockup enclosures inner and outer surfaces are with glued strain sensors, which outputs are also connected to recording and registering equipment hardware input. After processing of obtained experimental data forming data base on emergency situation development in case of accident at explosive facility and drawing up mathematical model, forecasting emergency prevention in case of accident at explosive facility.

EFFECT: technical result is increase in efficiency of process equipment and human resources protection from emergencies due to possibility of emergency situations development prediction in case of accident at explosive facility.

1 cl, 2 dwg

Description

The invention relates to chemical and general engineering, in particular to security systems that prevent the development of an emergency.

The closest technical solution to the claimed object is the device of emergency security systems according to the patent of the Russian Federation No. 2406904, А62С 35/00, dated 20.12.10 (prototype), containing a system of sensors installed in the danger zone of the protected object, which must be transferred from the usual operating mode in emergency mode as a result of the danger of an emergency, which is connected to the actuator, the operation of which receives a signal from the control device. Thus, the prototype uses a monitoring system with processing the received information about the danger zone to make a decision on preventing an emergency.

A disadvantage of the known solution is the relatively low information content for the control system for deciding on the introduction of an emergency mode of operation of the system and the inability to predict the development of an emergency.

A technically achievable result is an increase in the efficiency of protecting technological equipment and human resources from emergency situations by the ability to predict the development of an emergency in an accident at an explosive facility.

This is achieved by the fact that in the method for predicting the development of an emergency in an accident at an explosive hazardous facility, which consists in using a monitoring system with processing the received information about the hazardous area to make a decision on preventing an emergency, a model of the explosive facility is installed in the test box, and video cameras are installed on its internal and external perimeters for video surveillance of the development of an emergency in an accident at an explosive facility, which is fashionable they are set by installing an explosive fragmentation element with an explosion initiator in the prototype, while the cameras are explosion-proof, and the outputs from the cameras are connected to the unit through the internal cavity of the spacers, by means of which the process of changing the technological parameters in the model is recorded and recorded, and then recorded by systems of analyzers of recorded oscillograms of ongoing processes of changing technological parameters in the model of an explosive object, and in the ceiling In the first part of the model, an opening is made, which is closed by an explosion-proof element installed in a loose fit on three elastic pins, one end of each of which is rigidly fixed in the ceiling of the model, and on the second a horizontal crossbar is fixed, a three-coordinate pressure sensor in the explosion-proof is installed between the explosive fragmentation element and the opening performance, the output of which is connected to the input of the recording and recording equipment unit, and temperature and humidity sensors are located on both sides of the pressure sensor, controlling the humidity and humidity conditions in the layout, the outputs of which are also connected to the input of the recording and recording equipment block, and the internal and external surfaces of the layout fencing are glued with strain gauges, the outputs of which are also connected to the input of the recording and recording equipment block, and after processing the obtained experimental data, an information database is formed about the development of an emergency in an accident at an explosive facility and make up a mathematical model that predicts the prevention of emergency in an accident at an explosive facility.

In FIG. 1 shows a schematic diagram of a device for implementing a method for predicting the development of an emergency in an accident at an explosive facility, FIG. 2 - a fragment of the layout of the explosion-proof element in the ceiling of the layout.

A device for implementing a method for predicting the development of an emergency in an accident at an explosive object contains a model 1 of an explosive object (Fig. 1) with an explosive shrapnel element 14 installed with an explosion initiator 13, a protective cover 2 and a pallet 3, while the cover with a pallet is a single closed structure formed around the model 1 of an explosive object located in the test box 8. In addition, the model 1 is equipped with a transport 6 and suspension 5 systems, and the protective cover 2 is made of a multilayer th and consisting of facing inwardly to the layout of the aluminum layer 1, and then the rubber perkalevogo layers. The suspension system consists of a set of brackets and extensions 5 placed on the protective cover, as well as the required number of anchor hooks (loops) in the ceiling, walls and floor of the test box 8. Transport system 6 is designed to remove the destroyed layout 1 after testing from the test box 8 with protective cover 2.

The transport system is a drawbar cart. On the frame of the trolley spacers are mounted on which the pallet and breadboard are mounted 1. The suspension system consists of a set of brackets and extensions placed on a protective cover, as well as the required number of anchor hooks (loops) in the ceiling, walls and floor of the protective structure.

Inside the layout 1 of the explosive object, along its internal and external perimeters, video surveillance cameras 7 and 4 are installed for monitoring the emergency development process, modeled by an explosive fragmentation element 14 with an explosion initiator 13, and the video cameras 4 and 7 are made in explosion-proof design, and the outputs from the cameras through the internal the cavity of the spacers 10 is connected to the block 17 of the recording and recording equipment, the output of which is connected to the block of analyzers 18 of the recorded oscillograms of the ongoing processes of technological change Sgiach parameters in the model 1 explosive object. In the ceiling part of the layout 1, an opening 15 is made, which is closed by an explosion-proof element 16 installed in a loose fit on three elastic pins 19, one end of each of which is rigidly mounted in the ceiling of the layout 1, and the second has a horizontal crossbar. Between the explosive fragmentation element 14 and the aperture 15, made in the ceiling part of the layout 1 and the closed explosion-proof element 16, a three-coordinate pressure sensor 9 in the explosion-proof design is installed along the front of the blast wave, the output of which is connected to the input of the recording and recording equipment block 17. On both sides of the pressure sensor 9 are temperature sensors 20 and humidity 21, which control the thermo-humid mode in layout 1, the outputs of which are also connected to the input of block 17 of the recording and recording equipment. The inner surfaces of the protections of the layout 1 are glued with strain gauges 12 (strain gauges), and the outer surfaces are glued with strain gauges 11, the outputs of which are also connected to the input of the block 17 of the recording and recording equipment.

The device is mounted as follows: the pallet 3 with the help of spacers 10 and bolts (not shown in the drawing) is attached to the support legs (not shown in the drawing) of layout 1, and also through spacers (not shown) is bolted to the frame of the transport system 6 After the preliminary fitting and debugging of the suspension system 5, the protective cover 2 is tied to the ceiling of the test box 8 above the layout 1, the pallet 3 and the transport system 6. After preparatory operations for the detonation of the layout 1 and the explosive fragmentation element 14 with the initiator of the explosion 13, removing and sealing communications and connecting the corresponding electrical circuits, the cover is mounted around layout 1, hermetically connected to the pallet and stretched using a suspension system, forming a closed sealed space (volume) around layout 1. Internal and external surfaces of the protections of the layout 1 pasted with load cells 23 and 24.

The explosion-proof element 16, located in the ceiling part of the layout 1, where the opening 15 is made, and which is installed in a loose fit on three elastic pins 19, is additionally equipped with damping elements 26 (Fig. 2), mitigating the effects of the shock wave during an explosion and mounted on horizontal crossbars from the side facing the opening 15, while the elements 26 can be made of elastomer, for example polyurethane, or combined (not shown in the drawing), for example, elastic damping in the form of an elastic element, a spring filled polyurethane, and an inductive displacement sensor 22 is installed between the ceiling part of the layout 1 and the damping elements 26, which records the dynamics of the explosion-proof element 16 during an explosion, the signal from which passes through the communication line 25 to the recording and recording equipment block 17, the output of which is connected to the block 18 analyzers of recorded oscillograms of the ongoing processes of changing technological parameters in layout 1 of an explosive object.

The initiator of the explosion 13 of the explosive fragmentation element 14 can be used in flammable liquids. The oxidation equation of a stoichiometric mixture:

- количество молей кислорода;

- количество молей азота, углекислоты и воды (

); Q - теплота сгорания, ккал/(кг·моль).Where

- the number of moles of oxygen;

- the number of moles of nitrogen, carbon dioxide and water (

); Q is the calorific value, kcal / (kg · mol).

If we assume that all the heat of combustion of the oxidation reaction goes only to heat the combustion products, then the explosion temperature Twzr (adiabatic combustion temperature) can be determined from the heat balance of the oxidation reaction of the stoichiometric mixture:

- теплоемкости продуктов сгорания при температуре взрыва.Where

- the heat capacity of the combustion products at the temperature of the explosion.

[0,182 Дж/(кмоль·К)],

[0,163 Дж/(кмоль·К)],Accepted at T _explosion equal to 2000 ° C:

[0.182 J / (kmol · K)],

[0.163 J / (kmol · K)],

[0,115 Дж/(кмоль·К)].

[0.115 J / (kmol · K)].

The calculation of the required amount of explosive, for example a combustible liquid (acetone C ₃ H ₆ O) to create a stoichiometric concentration in the room is determined by the formula

where M is the molecular weight of the liquid; V _K - the volume of the room, l; V _In - the volume of air required for complete combustion of one molecule of a combustible liquid, l.

where P _bar - barometric pressure, mm Hg; Vo = 22.4 l - the volume of the gram molecule of air at 0 ° C and a pressure of 760 mm Hg,

volume (cm ³ ) of flammable liquid

where ρ is the density of the liquid, g / cm ³ .

A method for predicting the development of an emergency at an explosive facility is as follows.

In test box 8, a model 1 of an explosive object is installed, and video surveillance cameras 7 and 4 are installed along its internal and external perimeters for the development of an emergency in an accident at an explosive object, which is modeled by installing an explosive fragmentation element 14 with an explosion initiator 13 in model 1, while the cameras 4 and 7 are explosion-proof, and the outputs from the cameras through the internal cavity of the spacers 10 are connected to the block 17 and recording and registration of leaking processes of changing technological parameters in layout 1, after which they are recorded through a system of analyzers 18 recorded oscillograms of ongoing processes of changing technological parameters in layout 1 of an explosive object. In the ceiling part of the layout 1, an opening 15 is made, which is closed by an explosion-proof element 16 mounted in a loose fit on three elastic pins 19, one end of each of which is rigidly fixed in the ceiling of the layout 1, and a horizontal crossbar is fixed on the second. Between the explosive fragmentation element 14 and the aperture 15, a three-coordinate pressure sensor 9 is installed in an explosion-proof design, the output of which is connected to the input of the recording and recording equipment block 17, and temperature and humidity sensors 21 are located on both sides of the pressure sensor 9, which control the thermal and humid conditions in the layout 1, the outputs of which are also connected to the input of the block 17 of the recording and recording equipment. The inner surfaces of the protections of the layout 1 are glued with strain gauges 12 (strain gauges), and the outer ones with strain gauges 11, the outputs of which are also connected to the input of the recording and recording equipment block 17. After processing the obtained experimental data, an information database is formed on the development of an emergency in an accident at an explosive facility and a mathematical model is made that predicts the prevention of an emergency in an accident at an explosive facility. An explosion-proof element located in the ceiling part of the layout, where the opening is made, and which is installed in a loose fit on three elastic pins, is additionally equipped with damping elements that soften the effects of the shock wave in the explosion and is fixed on horizontal crossbars from the side facing the opening, while damping elements are made of elastomer, and an inductive displacement sensor is installed between the ceiling part of the layout and the damping elements, which records the dynamics of explosion of the final element in the explosion, the signal from which is sent through the communication line to the block of recording and recording equipment, the output of which is connected to the block of analyzers of recorded oscillograms of the ongoing processes of changing technological parameters in the model of an explosive object, after processing the obtained experimental data, an information database on the development of the emergency is formed in an accident at an explosive facility and make up a mathematical model that predicts the prevention of emergency accident at an explosive facility. At least two explosion-proof collapsing structures are placed in the side walls of the layout for fencing particularly hazardous production facilities that do not have window openings, and each of which consists of reinforced concrete panels consisting of collapsing and non-collapsing parts, and the non-collapsing part is made along the contour of the panel , and the collapsing part is performed in the form of at least two coaxially located niches, one of which is the outer one by the planes of a regular quadrangular truncated feast Foreign ministries with a rectangular base, and the other internal, are made in the form of two inclined surfaces connected by an edge, and strain sensors are installed on the inclined surfaces of the collapsing part of the panel, fixing the deformation and the moment of their destruction, while the signal from the strain gauges is sent through the communication line to the recording and recording unit equipment, the output of which is connected to a block of analyzers of recorded oscillograms of the ongoing processes of changing technological parameters in the model of an explosive object, after processing The obtained experimental data form an information database on the development of an emergency in an accident at an explosive facility and make up a mathematical model that predicts the prevention of an emergency in an accident at an explosive facility.

Claims (1)

A method for predicting the development of an emergency at an explosive facility, which consists in using a monitoring system with processing the received information about the hazardous area to make a decision on preventing an emergency, installing a model of the explosive facility in the test box, and installing video cameras for its internal and external perimeters video surveillance of the emergency development process in the event of an accident at an explosive facility, which is modeled by installation in a breadboard explosive fragmentation element with an initiator of explosion, while the cameras are explosion-proof, and the outputs from the cameras through the internal cavity of the spacers are connected to the unit, by means of which they record and record the ongoing processes of changing technological parameters in the layout, after which they are recorded through a system of analyzers of recorded oscillograms of the proceeding processes of changing technological parameters in the model of an explosive object, and in the ceiling part of the model, an opening is performed to the other is closed by an explosion-proof element installed in a loose fit on three elastic pins, one end of each of which is rigidly fixed in the ceiling of the layout, and on the second a horizontal crossbar is fixed, an explosion-proof three-coordinate pressure sensor is installed between the explosive fragmentation element and the opening, the output of which is connected to the input unit of the recording and recording equipment, and on both sides of the pressure sensor are temperature and humidity sensors that control the thermal humidity mode m in the layout, the outputs of which are also connected to the input of the recording and recording equipment block, and the internal and external surfaces of the protections of the layout are glued with strain gauges, the outputs of which are also connected to the input of the recording and recording equipment block, after processing the obtained experimental data, an information database on the development of emergency situations in an accident at an explosive facility and make up a mathematical model that predicts the prevention of an emergency in an accident at an explosion hazardous object, while the explosion-proof element located in the ceiling part of the layout, where the opening is made, and which is installed in a loose fit on three elastic pins, is additionally equipped with damping elements that soften the effects of the shock wave during the explosion, and is fixed on the horizontal bars from the side facing to the opening, while the damping elements are made of elastomer, and an inductive displacement sensor is installed between the ceiling part of the layout and the damping elements, which records the dyn the dynamics of the movement of the explosion-proof element during an explosion, the signal from which is sent through a communication line to a block of recording and recording equipment, the output of which is connected to a block of analyzers of recorded oscillograms of ongoing processes of changing technological parameters in the model of an explosive object, after processing the obtained experimental data, an information database on development emergency during an accident at an explosive facility and make up a mathematical model that predicts prevented e emergency during the accident at an explosive object, characterized in that the test cell is used in a flammable liquid initiator explosive blast fragmentation member, such as acetone, with its required amount is determined by the formula for creating the stoichiometric concentration in test cell
$$g=\frac{M{V}_{\mathrm{to}}}{V_{\mathrm{at}}}(\mathrm{one})$$

where M is the molecular weight of the liquid; V _K is the volume of the test box, l; V _In - the volume of air required for complete combustion of one molecule of a combustible liquid, l.

where P _bar - barometric pressure, mm RT. st .; Vo = 22.4 L is the volume of a gram molecule of air at 0 ° C and a pressure of 760 mm Hg. Art., volume (cm ³ ) of flammable liquid

where ρ is the density of the liquid, g / cm ³ .

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