RU2652032C1 - Stand for investigation of the parameters of explosive protection devices in a test mock-up of an explosive object - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to machine building and can be used for explosion protection of process equipment. This is achieved by the fact that in the method for determining the effectiveness of the explosion-proof device in the test model of the explosive object, the model of the explosive object is installed in the test box, and along its internal and external perimeters the video cameras are installed for video surveillance, while video cameras are made in explosion proof performance, and the outputs from the video cameras through the inner cavity of spacers are connected to the unit through which the recording and registering of the process of changing of the technological parameters in the mock-up are performed, then registering by means of system analyzers recorded processes waveforms, change of explosive object process parameters in the mock-up of the explosive object, and in the ceiling part of the model the opening is made, which is closed with the explosion-proof element that is installed on the free landing using three elastic pins, one end of each of which is rigidly fixed into the ceiling of the model, and onto the second end the horizontal crossbar is attached, between the explosive fragment and the opening, the three-coordinate pressure sensor in the explosion-proof design is installed, which output is connected to recording and registering equipment unit input, and on both sides of the pressure sensor there are temperature and humidity sensors that control the thermal mode in the model, the outputs of which are also connected to the input of the recording and registering equipment, and model enclosures inner and outer surfaces are pasted with strain sensors, which outputs are also connected to recording and registering equipment unit input, after processing of the experimental data, the information database is developed on the emergency situation development in case of the accident at the explosive site, and a mathematical model is created to forecast prevention of the emergency in case of an accident on the explosive object.

EFFECT: higher efficiency of process equipment protection against explosions by increasing the efficiency and reliability of bursting elements’ response.

1 cl, 4 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 effectiveness of an explosion-proof device of RF patent No. 2488074, F16D 3/04 (prototype), in which they test the valve body, shutter, heat insulating and bursting elements.

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 test bench for examining the parameters of explosion-proof devices in a test model of an explosive object, a model of an explosive object is installed in the test box, and video surveillance cameras are installed along its internal and external perimeters, while the cameras are explosion-proof and the outputs from the video cameras through the internal cavity of the spacers are connected to the unit, through which record and registration of ongoing processes of changing technological pairs of meters in the layout, after which, through a system of analyzers of recorded oscillograms of the ongoing processes, the technological parameters in the model of the explosive object are recorded, and in the ceiling part of the layout there is an opening that is closed by an explosion-proof element mounted on a loose fit on three elastic pins, one end of each of which is rigidly fix in the ceiling of the layout, and on the second - fix the horizontal bar, between the explosive fragmentation element and the aperture, install three-coordinate sensors pressure in explosion-proof 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 the internal and the 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 unit, after processing the received The 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.

In FIG. 1 shows a general schematic diagram of a test bench for examining the parameters of explosion-proof devices in a test model of an explosive object, FIG. 2 is a diagram of the ceiling part of the layout, in FIG. 3 - arrangement of strain gauges on a dynamometer, corrected with the general circuit diagram of the device according to the positions of the block 17 of recording and recording equipment, the output of which is connected to a block of analyzers 18 of recorded oscillograms of the ongoing processes of changing technological parameters in model 1 of an explosive object, in FIG. 4 is a diagram of an embodiment of the ceiling part of the layout.

The test bench for studying the parameters of explosion-proof devices in a test model of an explosive object contains a model 1 of an explosive object with an explosive shrapnel element 14 mounted therein, 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 breadboard model 1 of an explosive object located in the test box 8. In addition, breadboard model 1 is equipped with transport 6 and suspension 5 systems, and the protective cover 2 is multilayer and consists of facing inwardly to the layout 1 of the aluminum layer, then the rubber and percale 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.

On the pins 19 (Fig. 2), to their horizontal crossbeam (stop sheets), dynamometers 20 (Fig. 3) are mounted, designed to measure the explosive force developed by the explosion-proof element 16 mounted on a loose fit on three elastic pins 19 above the opening 15. Each of the dynamometers 20 is made in the form of at least two leaf springs 21 and 22, one end of each of which is rigidly fixed on the stop sheets, and the second on the sleeve 23 that is freely placed and covering the pins. In this case, the leaf springs 21 and 22 made arch type with bulge directed away from the pins, and on the peripheral part of the convexity of each leaf spring 21 and 22, strain gages 24 and 25 are fixed, moreover, on one spring 21 - from the inside, and on the other 22 - from the outside to record both compression stresses and tension, while the signals from the strain gauges 24 and 25 are fed through channels 26 and 27 to the strain gauge 28, and from it to the block 17 (Fig. 1) of the recording and recording equipment, the output of which is connected to the analyzer block 18 (Fig. 1) recorded oscillograms of the ongoing processes of changing technological parameters in layout 1 of an explosive object.

Between the explosive fragmentation element 14 and the opening 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.

To the horizontal crossbar of the pins 19 (Figs. 2 and 3), the upper part 31 of the inductive displacement sensor (Fig. 3) is fixed, which is designed to measure the vertical rise of the explosion-proof element 16 from the explosive force through the opening 15 located in the ceiling of the layout 1, and the lower part 32 of the inductive displacement sensor is rigidly fixed in the ceiling part of the layout 1, located next to the explosion-proof element 16, while the signal from the inductive displacement sensor through the channel 33 enters the strain gauge 28, and from it to the block 17 (Fig. 1) for isyvayuschey and the recording apparatus, the output of which is connected to the analyzer unit 18 (FIG. 1) of the processes recorded waveform changing process parameters in the layout of one explosive object.

An inductive displacement sensor is designed to record the vertical rise of the explosion-proof element 16 from the explosive force developed from the explosive fragmentation elements 14.

On both sides of the pressure sensor 9 are temperature sensors 29 and humidity 30 (Fig. 1), 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) is attached to the support legs (not shown) 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 is tied to the ceiling of test box 8 above layout 1, pallet 3 and transport system 6. After preparatory operations to undermine operations with layout 1 and explosive fragmentation element 14 with the initiator of the explosion 13, removal and sealing of communications and connecting In accordance with 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 tight space (volume) around layout 1.

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 smaller in TNT than the subsequent ones, while additional video surveillance cameras made in explosion-proof execution, and carry out an additional assessment of the effectiveness of explosion-proof execution of explosive fragmentation elements, and determine wherein the means of computer simulation scale emergency in explosions in blasting storage fission sites.

The stand for researching the parameters of explosion-proof devices in a test model of an explosive object works 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 installed 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 the 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 29 are located on both sides of the pressure sensor 9, which control the moisture and humidity 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 block 17 of the recording and recording equipment. In this case, the tests begin with an explosive fragmentation element, which is smaller in TNT equivalent than the subsequent ones, while additional video surveillance cameras are installed, which are designed in explosion-proof version, and they additionally evaluate the effectiveness of the explosion-proof version of explosive fragmentation elements, and determine the extent of this using computer simulation 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.

A variant is possible (Fig. 4), when a damping plate is rigidly fixed to the horizontal crossbar of the pins 19, on which the upper part 31 of the inductive displacement transducer, designed to measure the vertical lift of the explosion-proof element 16 from the explosive force through the opening 15, is fixed, from the side of the explosion-proof element 16 34, to which the opposite panel and in the direction of the shock wave attached buffer device 35, made in the form of a cone, the top of which is located on the axis of the opening 15 of the protected object.

A variant is possible (Fig. 4) when the inner cavity of the damping plate 34 is filled with a three-layer symmetric disperse system, while the central layer (not shown), which is the symmetry layer of the damping plate 34, as a three-dimensional body with an internal cavity, and surfaces equidistant to the panel surfaces are made of vibration damping material, and the layers adjacent to it are filled with an air-lead dispersed system.

An embodiment of the damping plate 34 is possible when the central layer, which is the symmetry layer of a three-dimensional body with an internal cavity, and surfaces equidistant to the panel surfaces, are combined, consisting of three layers: the middle layer is made of a hard vibration-damping material, for example, “Agate” or “ “Anti-vibration”, and the upper and lower layers symmetrically located relative to it are made of continuous damping material in which sponge rubber or needle-punched material is used na "shale shakers" based on silica or aluminoborosilicate fibers or nonwoven vibration damping material (not shown).

A variant is possible (Fig. 4) when the buffer device 35, rigidly mounted on the damping plate 34, is made in the form of a hollow cone of a rubber-cord shell filled with compressed air (gas), in which a bursting membrane 36 with a strain gauge is placed, the signal from which is through a strain gauge 28, enters the block 18 for processing recorded waveforms of ongoing processes of changing technological parameters in layout 1 of an explosive object.

Claims (2)

1. A test bench for studying the parameters of explosion-proof devices in a test model of an explosive hazardous facility, containing systems for monitoring and processing information received about the hazardous area, it contains a model of an explosive hazardous facility with an explosive fragmentation element installed in it with an explosion initiator, a protective cover and a pallet, in this case, the cover with the pallet is a single closed structure formed around a model of an explosive object, and the model is equipped with a transport and suspension system stems, while the protective cover is multilayered and consisting of the aluminum layer facing inward to the layout, then the rubber and percale layers, and the suspension system consists of a set of brackets and extensions placed on the protective cover, as well as the required number of anchor hooks in the ceiling, walls and the floor of the test box, and inside the model of the explosive facility, along its internal and external perimeters, video surveillance cameras are installed, made in explosion-proof design, and the outputs from the cameras are connected to the unit com of recording and recording equipment, the output of which is connected to the analyzer block 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 model there is an opening that is closed by an explosion-proof element installed in a loose fit on three elastic pins, one end of each which are rigidly mounted in the ceiling of the layout, and on the second - there is a horizontal crossbar, and between the explosive fragmentation element and the opening made in of the part of the prototype, and a closed explosion-proof element along the front of the blast wave, a three-coordinate pressure sensor is installed in an explosion-proof design, the output of which is connected to the input of the recording and recording equipment, and temperature and humidity sensors are located on both sides of the pressure sensor, which monitor the thermal and humid conditions in the prototype 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 model fences are glued t with sensors, the outputs of which are also connected to the input of the recording and recording equipment unit, characterized in that the layout contains a set of explosive fragmentation elements, consisting of at least two explosive fragmentation elements, respectively connected to the initiators of the explosion, while installing additional video surveillance cameras made in explosion-proof execution, and conduct an additional assessment of the effectiveness of explosion-proof execution of explosive fragmentation elements, and determine in this case by means of computer simulation, the scale of an emergency during explosions at objects for storing explosive fragmentation elements, and on the pins, to their horizontal crossbar, fasten dynamometers designed to measure the explosive force developed by the explosion-proof element, which is set by free landing on three elastic pins above the opening, moreover, each of the dynamometers is made in the form of at least two leaf springs, one end of each of which is rigidly fixed to the support sheets, and the second to the free one of the bushings located and covering the pins, while the leaf springs perform an arch type with a bulge directed away from the pins, and strain gages are fixed on the peripheral part of the bulge of each leaf spring, with one spring on the inside and the other on the outside registration of both compressive and tensile stresses, and to the horizontal bar of the pins, the upper part of the inductive displacement transducer is designed to measure the vertical rise of the explosion-proof element from at the same time, through the opening located in the ceiling part of the layout, the lower part of the inductive displacement sensor is rigidly fixed in the ceiling part of the layout located near the explosion-proof element, and the signal from the inductive displacement sensor is fed to the strain gauge, and from it 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, and the buffer device rigidly mounted on a damping plate and made in the form of a hollow cone made of rubber-cord shell filled with compressed air, in which a bursting disc with a strain gauge is placed, the signal from which is fed through the strain gauge to the processing unit for recorded oscillograms of the occurring processes of changing technological parameters in the model of an explosive hazardous object. 2. A stand for examining the parameters of explosion-proof devices in a test model of an explosive object according to claim 1, characterized in that to the horizontal crossbar of the pins, on which the upper part of the inductive displacement sensor is fixed, designed to measure the vertical lift of the explosion-proof element from the explosive force through the opening, with the side of the explosion-proof element, a damping plate is rigidly fixed, to which a buffer device is made, opposite to the panel and in the direction of the shock wave in the form of a cone, the vertex of which is on the axis of the opening of the protected object.

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