RU2613986C1 - Method for determining efficiency of explosion protection - Google Patents

Abstract

FIELD: blasting.

SUBSTANCE: monitoring system is used together with processing of the received information about a danger zone in the test box, where the explosive object layout is set. Video cameras are set in the inner and outer perimeters of the layout to video monitor the development of an emergency. Changes in the technological parameters of the explosive object layout are recorded via the system of analyzers of conducting processes recorded oscillograms, and an opening is made on the layout ceiling part. A triaxial explosion-proof pressure sensor is set between the explosive fragmentation element and the opening. Temperature and humidity sensors are mounted on both sides of the pressure sensor. Internal and external surface of the layout fencing is pasted with strain gauges. An information data base of the emergency development is created and a mathematical model is configured predicting emergency prevention in the accident.

EFFECT: increase efficiency of technological equipment protection from explosions via increasing speed and reliability of explosive elements operation.

3 cl, 3 dwg

Description

The invention relates to mechanical engineering and can be used for explosion protection of technological equipment.

The closest technical solution to the claimed object is a method for determining the efficiency of an explosion-proof device of RF patent No. 2548256 F 16 D 3/04, (prototype), a model of an explosive object is installed in the test box, and video cameras are installed along its internal and external perimeters, while the video cameras perform in the explosion-proof design, and the outputs from the cameras through the internal cavity of the spacers are connected to the unit, through which recording and registration of ongoing processes of technological change parameters in the layout, after which they are recorded through a system of analyzers of recorded oscillograms of the ongoing processes of changing technological parameters in the model of an explosive object, and in the ceiling part of the layout, 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 rigidly fixed in the ceiling of the layout, and on the second they fix the horizontal bar, between the explosive fragmentation element and the aperture set three-coordinate explosion proof pressure sensor, the output of which is connected to the input of the recording and recording equipment unit, and on both sides of the pressure sensor there are temperature and humidity sensors that control the humidity and humidity conditions in the layout, the outputs of which are also connected to the input of the recording and recording equipment unit, and the internal and external surfaces of the protections of the layout are glued with load cells, the outputs of which are also connected to the input of the recording and recording equipment unit, after processing the floor ennyh experimental data form the information base for the development of emergency data in a crash on explosive objects and make a mathematical model predicting the prevention of an emergency at the hazardous facility accident. A disadvantage of the known solution is the relatively low reliability of operation of the bursting disc.

The technical result is an increase in the efficiency of protection of technological equipment from explosions by increasing the speed and reliability of the operation of explosive elements.

This is achieved by the fact that in the method of determining the effectiveness of an explosion-proof device with a bursting disc, a model of an explosive object is installed in the test box, and video cameras for video surveillance are installed along its internal and external perimeters, while the cameras are executed in explosion-proof design, and the outputs from the cameras through the internal cavity of the spacers connected to the unit, through which record and register the ongoing processes of changing technological parameters in the layout, after four о register, through a system of analyzers of recorded oscillograms of the ongoing processes, changes in technological parameters in the model of an explosive object, and in the ceiling part of the model, an opening is made, which is closed by an explosion-proof element installed on 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 mounted, between the explosive fragmentation element and the opening, a three-coordinate pressure sensor is installed in the explosion-proof execution, the output of which is connected to the input of the recording and recording equipment unit, and on both sides of the pressure sensor there are temperature and humidity sensors that control the thermo-humid mode in the layout, the outputs of which are also connected to the input of the recording and recording equipment unit, and the internal and external surfaces of the fencing the model is pasted over with load cells, the outputs of which are also connected to the input of the recording and recording equipment block, after processing the obtained experimental data miruyut information base for the development of emergency data in the hazardous site of the accident and make a mathematical model predicting the prevention of an emergency at the hazardous facility accident.

In FIG. 1 shows a schematic diagram of a device for implementing a method for determining explosion protection efficiency; FIG. Figures 2 and 3 show explosion-proof circuit diagrams with a built-in safety indicator and damping elements.

A device for implementing the method for determining the effectiveness of explosion protection contains a model 1 of an explosive object with an explosive fragmentation element 14 installed therein with an explosion initiator 13, a protective cover 2 and a pallet 3, the cover with a pallet being a single closed structure formed around the model 1 of an explosive object, placed in the test box 8. In addition, the layout 1 is equipped with a transport 6 and suspension 5 systems, and the protective cover 2 is multilayer and consists of aluminum facing inward to the layout 1 inievogo layer, 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 a pallet and layout 1 are mounted and mounted. Inside layout 1 of an explosive object, along its internal and external perimeters, video surveillance cameras 7 and 4 are installed for monitoring the emergency development process, modeled by means of an explosive fragmentation element 14 with an explosion initiator 13 moreover, the cameras 4 and 7 are made in explosion-proof execution, and the outputs from the cameras through the internal cavity of the spacers 10 are connected to the recording and recording equipment unit 17, the output of which is connected to Locke analyzer 18 processes the recorded waveforms occurring changes of process 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 recording and recording equipment. The device is mounted as follows: the pallet 3 with the help of spacers 10 and bolts (not shown) 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. Protective cover 2 after preliminary fitting and debugging of the suspension system 5, it 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 va 13, communications excretion and sealing and connecting respective electric circuits mounted around Case 1 layout sealingly connected to sump and is stretched by a suspension system, forming a sealed closed space (volume) of around 1 layout.

In layout 1, a set of explosive fragmentation elements 14 is installed, consisting of at least two explosive fragmentation elements connected respectively to the initiators of the explosion 13, and the tests begin with an explosive fragmentation element, which is smaller in TNT than the subsequent ones, while additional cameras are installed video surveillance performed in explosion-proof performance and conduct an additional assessment of the effectiveness of explosion-proof performance of explosive fragmentation elements and determine at the same time, by means of computer simulation, the scale of an emergency during explosions at storage facilities for explosive fragmentation elements.

An embodiment of the explosion-proof element 16 (Fig. 2) is possible, which is installed in the ceiling part of the layout 1, where an opening 15 is made, which is closed by this explosion-proof element 16, which is installed in a loose fit on three elastic pins 19 with stop sheets 25, one end of each of which it is rigidly mounted in the ceiling of the layout 1, and on the second there is an additional element 27 made of elastomer, for example polyurethane. Additional elements 27 can be made combined (not shown), for example, elastically damping in the form of an elastic element, for example, a spring filled with polyurethane. Between the additional elements 10 and the metal frame with armored metal sheathing 16 on the supporting rods 19 are installed sleeves 26 made of quick-breaking material, for example, triplex glass.

The built-in emergency warning system with a safety indicator consists of a “weak link” attachment point in the security system of an explosive facility that responds to an emergency, made, for example,

 in the form of a safety indicator 22, mounted between flanges 28 and 29, which are rigidly fixed on the upper part of the armored metal sheathing 16 (flange 28) of the metal frame of the explosion-proof element, and in the upper part of the coating of the explosive object at the opening 15 (flange 29), designed to be dropped overpressure. The safety indicator 22 consists of a sensor that responds to deformation, for example, a strain gauge (strain gauge), the output of which is connected to a signal amplifier, for example a strain gauge 23, and the output of the strain gauge 23 is connected to the input of the emergency warning system 24.

The safety indicator of the emergency warning system works as follows.

The emergency response unit, made in the form of a sensor mounted on a discontinuous element, for example, in the form of a stud with a section of a smaller cross section, experiences a tensile deformation, the signal of which is fed to the input of the amplifier 23, and the output from the amplifier 23 is connected to the input of the warning device 24 about the emergency.

The device explosion protection of hazardous facilities with an emergency warning system operates as follows.

In an explosion inside an industrial building (not shown in the drawing), the panel rises from the action of the shock wave and overpressure is released through the open opening 15. First, the explosion-proof element overcomes the resistance of the sleeve 26 of glass, and after its destruction, the resistance of additional elements made by combined, for example, elastic-damping, in the form of an elastic element, for example, a spring filled with polyurethane.

A variant is possible (Fig. 3) when, to fix the limit position of the explosion-proof element 16, a damping element 30 is attached to the ends of the supporting elastic rods 19 with stop sheets 25, which is designed to damp the shock loads of the explosion-proof element 16 against the stop sheets 25.

The damping element 30 is attached opposite the panel and is directed towards it, i.e. towards her movement during the explosion.

The damping element 30 is made in the form of a three-dimensional body with an internal cavity and surfaces equidistant to the surfaces of the explosion-proof element 16, while its internal cavity is filled with a dispersed air-lead system, and lead is made in the form of crumbs, spherical in shape.

When the panel moves explosively upward along the elastic rods 19, it encounters a damping element 30 in its path, upon interaction with which the energy of the explosion is suppressed.

The method of determining the effectiveness of explosion protection 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 unit 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 model 1 are glued with load cells 12 (strain gauges), and the external surfaces are glued with load sensors 11, the outputs of which are also connected to the input of the recording and recording equipment unit 17. In this case, the tests begin with an explosive fragment fragment, which is smaller in terms of TNT, compared to the following, at the same time install additional video surveillance cameras made in explosion-proof performance, and conduct an additional assessment of the effectiveness of explosion-proof performance of explosive fragments full-time elements, and then determine by computer simulation the extent of the emergency during explosions at storage facilities for explosive fragmentation elements. After processing the obtained experimental data, a mathematical model is made that predicts accidents at an explosive facility.

Claims (3)

1. A method for determining the effectiveness of explosion protection, which consists in using a monitoring system with the processing of the received information, installing a model of an explosive object in the test box, and installing video cameras along its internal and external perimeters, while the cameras are designed in explosion-proof design and the outputs from the video cameras through the internal cavity of the spacers are connected to the block, through which the process of changing the technological parameters is recorded and recorded in the layout and then, through a system of analyzers of recorded oscillograms of the ongoing processes, they record changes in technological parameters in the model of an explosive object, and in the ceiling part of the model, an opening is made, which is closed by an explosion-proof element mounted on a loose fit on three elastic pins, one end of each of which is rigidly fixed in the ceiling the layout, and on the second - they fix the horizontal bar, between the explosive fragmentation element and the aperture a three-coordinate pressure sensor is installed in a fireproof design, the output of which is connected to the input of the recording and recording equipment unit, and on both sides of the pressure sensor there are temperature and humidity sensors that control the thermo-humid mode in the layout, the outputs of which are also connected to the input of the recording and recording equipment unit, and internal and external surfaces protections of the layout are pasted over with load cells, the outputs of which are also connected to the input of the recording and recording equipment unit, after processing the obtained experimentally The data is compiled into an information database on the development of an emergency in case of an accident at an explosive facility and a mathematical model is made that predicts the prevention of an emergency during an accident at an explosive facility, characterized in that a set of explosive fragmentation elements consisting of at least two explosive fragmentation elements, respectively, with the initiators of the explosion, while the tests begin with an explosive fragmentation element, smaller in TNT equivalent in comparison with subsequent, moreover, additional video surveillance cameras are installed, made in explosion-proof execution, carry out an additional assessment of the efficiency of explosion-proof execution of explosive fragmentation elements and determine the extent of emergency situations during explosions at storage facilities for explosive fragmentation elements by computer simulation. 2. The method for determining the efficiency of explosion protection according to claim 1, characterized in that on the weak link elements in the emergency safety system, for example explosion-proof elements, on the elastic pins of which are installed sleeves of rapidly breaking material, for example, triplex glass, an emergency warning system is installed while a safety indicator is fixed between the metal frame with the armored metal casing and the upper part of the coating of the explosive object at the opening intended to relieve excess pressure It acts as a weak link in the security system of an explosive hazardous facility and responds to an emergency, which is performed in the form of a sensor that responds to deformation, for example, a strain gauge, the output of which is connected to a signal amplifier, such as a strain gauge, and the output of the strain gauge is connected to the input of the warning system about the emergency. 3. The method for determining the efficiency of explosion protection according to claim 1, characterized in that for fixing the limit position of the explosion-proof element, a damping element is attached to the ends of the elastic pins with stop sheets, which is designed to damp the shock loads of the explosion-proof element against the stop sheets, and attach the opposite to the explosion-proof element and directed towards the explosion-proof element, and performed in the form of a volumetric body with an internal cavity and surfaces equidistant to the surfaces of the explosion-proof element, while its internal cavity is filled with a dispersed air-lead system, and lead is made in the form of spherical crumbs.

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