RU2669180C2 - Kochetov method of simulation of emergency situation - Google Patents

Abstract

FIELD: safety systems.SUBSTANCE: invention relates to safety systems preventing development of emergency situations. This is achieved by the fact that in the stand for simulation of an emergency situation, containing a mock-up of an explosive object installed on racks, with the initiator of the explosion installed in it, protective cover and tray, at that, the cover with the tray represent the single enclosed structure formed around the located in the test box explosive facility mock-up, at that, the mock-up is equipped with transportation and suspension systems, and the protective cover is made multilayered and consisting of facing inside the mock-up aluminum layer, as well as rubber and percale layers, model of the explosive object is equipped with the object to be examined on the stand: an explosion-proof element installed above the hole in the upper part of the layout, which consists of an armored metal frame with armored metal lining and filler-lead, and in the mock-up upper part, at the hole, symmetrically relative to its axis, four support rods are embedded, telescopically inserted into the stationary branch pipes supports embedded into the explosion-proof element panel, and for the panel limit position fixation, to the support rods ends support sheets are welded in.EFFECT: technically achievable result is to increase the efficiency of protection of technological equipment and human resources from emergency situations by the possibility of forecasting the development of an emergency situation in an accident at an explosive site.1 cl, 4 dwg

Description

The invention relates to security systems that prevent the development of an emergency.

The closest technical solution to the claimed object is an emergency safety device according to the patent of the Russian Federation No. 2564209, А62С 35/00, (prototype), containing a model of an explosive object mounted on racks, with an explosion initiator installed in it.

A disadvantage of the known solution is the relatively low reliability 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 emergency simulator, which contains a model of an explosive hazardous object mounted on racks, with an explosion initiator installed in it, a protective cover and a pallet, while the cover with a pallet is a single closed structure formed around a model of an explosive object placed in a test box, while the layout is equipped with transport and suspension systems, and the protective cover is multilayer and consists of an aluminum layer facing inward to the layout, and e perkalevogo rubber and layers of an explosive object layout on the test stand is equipped with an object: Ex-member mounted over an opening in the top of the layout, which consists of an armored metal frame with metal armor plating and excipient - with lead.

In FIG. 1 shows a schematic diagram of a stand for modeling an emergency in an accident at an explosive facility, FIG. 2 - a diagram of an explosion-proof element installed in the ceiling part of the model of an explosive object is presented; FIG. 3 is a diagram of an explosion-proof element installed in the lateral part of a model of an explosive object; FIG. 4 is an embodiment of an elastic damping element.

A device for simulating an emergency in an accident at an explosive object (Fig. 1) contains a model 1 of an explosive object mounted on racks 2, with an explosion initiator 3 installed in it, a protective cover 4 and a pallet 5, while the cover with a pallet is a single closed structure formed around the model 1 of an explosive object placed in the test box 6. In addition, the model 1 is equipped with a transport 7 and a suspension 8 systems, and the protective cover 4 is made of multilayer and consisting of facing inward to the layout 1 of the aluminum layer, then the rubber and percale layers. The suspension system 8 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 test box 6. The transport system 7 is designed to remove the broken layout 1 after testing from the test box 6 with protective cover 4.

The model 1 of an explosive object is equipped with an object studied at the stand: an explosion-proof element 9 (Fig. 2) installed above the hole 10 in the upper part of the model. Explosion-proof element 9 consists of an armored metal frame 11 with armored metal casing 12 and a filler - lead. In the upper part of the layout 1, at the hole 10, four support rods 13, telescopically inserted into the fixed nozzle supports 14, embedded in the panels of the explosion-proof element 9, are sealed symmetrically relative to its axis. For fixing the limit position of the panel, sheets are welded to the ends of the support rods 13 - stops 15. In order to damp (soften) shock loads when the panel is returned, the filler is made in the form of a dispersed air-lead system, moreover, the lead is made in the form of crumbs, and the support rods 13 can be made elastic E.

Outside of the support rods 13 are resiliently damping elements 16, one end of which abuts against an armored metal sheathing 12, and the other into abutment sheets 15 located in the upper part of the support rods 13.

A variant of the elastic-damping element 16 (Fig. 4) is possible, which is made with a quick-breaking single-acting element in the form of a sleeve 25 of a brittle, collapsing material, for example porcelain, which is attached to the stop sheets 15 by means of a damping base 21, fixed to the stop sheets 15 by screws 22. To the base 21, coaxially to the rod 13, is attached by a flange 23 with screws 24 of a sleeve 25 of a single-acting action.

The elastic part of the elastic damping element 16 is made in the form of at least three leaf springs 29 located between the stop sheets 15 and the clamping element 26 of the sleeve type with grooves 28 for fixing one end of the springs 29, while the second end of each spring 29 by means of hinges 30 fixed on the stop sheets 15, and the springs 29 are located with an inclination of the order of 15 ° ÷ 45 ° in the direction of the quick-breaking single-acting element in the form of a sleeve 25.

The filler may be made in the form of spherical chips of one diameter; in the form of spherical crumbs of different diameters. The filler can be made in the form of crumbs of arbitrary shape of different diametric (maximum external, arbitrary shape, contour of the crumb) size.

In addition, the model 1 of an explosive object is equipped with an object studied at the stand: an explosion-proof element 17 (Fig. 3) installed in the side of the layout, and which is identical to the explosion-proof element installed in the upper part of the layout.

A device for simulating an emergency operates as follows.

In test box 8, a model 1 of an explosive object with two explosion-proof elements is installed: in the upper (ceiling) part of the model and in the side of the model, the structures of which are identical. In the upper (ceiling) part of the layout 1 and in the side part, openings 10 (openings) are made, which are closed by explosion-proof elements 9 and 17, installed on loose fit on three elastic pins 13, one end, each of which is rigidly fixed in the ceiling of the model 1 and on the second a horizontal crossbar is fixed in the form of stop sheets 15. After the initiator of the explosion 3 is triggered, a situation analysis is carried out, and after processing the received experimental data, an information database on the development of an emergency in an accident voopasnom object and make a mathematical model predicting the prevention of an emergency at the hazardous facility accident.

On the outside of the layout, near the explosion-proof elements 9 and 17, armored cameras 18 and 19 are installed, the outputs of which are connected to a computer 20 that records the moments of operation of the explosion-proof elements 9 and 17, and as a result of processing these signals, conclusions are made about the distribution of blast waves in the volume premises.

Each of the explosion-proof elements 9 and 17 operates as follows.

When an explosion occurs inside the layout 1, the panel of the explosion-proof element 9 rises from the action of the shock wave and overpressure is released through the open opening 10.

In this case, the elastic damping elements 16 are compressed, absorbing the energy of the explosion, and then return the panel 9 to its original state.

The outer screw surface of the elastic damping elements 16 is covered with vibration damping mastic, for example, type VD-17, which additionally contributes to the damping of the blast wave.

After the explosion and the drop in excess pressure, dropping down, the panel closes the opening 10 and harmful substances do not enter the atmosphere. To fix the limit position of the panel, stop sheets 15 are used. In order to damp (soften) shock loads when the panel is returned, the filler of the metal frame 11 is made in the form of a dispersed air-lead system, moreover, the lead is made in the form of crumbs, and the support rods 13 can be made elastic.

The method for modeling an emergency at an explosive facility is as follows.

The model of an explosive object is installed on racks, equipped with a protective cover with a pallet, as well as transport and suspension systems, the protective cover is multi-layer and consists of an aluminum layer facing inward to the model, as well as rubber and percale layers, the model of an explosive object is equipped with the objects studied on the stand: explosion-proof elements, and inside the layout set the initiator of the explosion. The model of the explosive object is additionally equipped with an explosion-proof element installed in the lateral part of the model, which is identical to the explosion-proof element installed in the upper part of the model, and on the outside of the model, near the explosion-proof elements, armored cameras are installed, the outputs of which are connected to a computer recording the moments of operation of the explosion-proof elements, and as a result of processing these signals, an analysis is performed of the distribution of blast waves in the volume of the room, and pa the nel additionally contains one-time elastic-damping collapsing elements that are attached to the support rods to the abutment sheets by means of a damping base with screws, and a disposable sleeve made of brittle, collapsing material, such as porcelain, is attached to the base, coaxial to the rod, with screws. the elastic part of the collapsing element is made in the form of at least three leaf springs placed between the stop sheets and the clamping element of the sleeve na with grooves for fixing one end of the spring, the second end of each spring is fixed by hinges at the stop-plates and springs arranged with a slope of about 15 ° ÷ 45 ° in the direction of elastic-damping element collapsing disposable.

Claims (1)

A method for modeling an emergency at an explosive facility, namely, that the model of an explosive facility is mounted on racks, equipped with a protective cover with a pallet, as well as transport and suspension systems, the protective cover is multi-layer and consists of an aluminum layer facing the breadboard inward as well as a rubber and percale layers, the model of an explosive object is equipped with the objects studied at the stand: explosion-proof elements, and an explosion initiator is installed inside the model, characterized in that then the model of the explosive object is additionally equipped with an explosion-proof element installed in the lateral part of the model and which is identical to the explosion-proof element installed in the upper part of the model, and on the outside of the model, near the explosion-proof elements, armored cameras are installed, the outputs of which are connected to a computer recording the moments of operation of the explosion-proof elements, and as a result of processing these signals, they analyze the distribution of blast waves in the volume of the room, and the panel additionally contains one-time elastically damping collapsing elements that are attached to the support rods to the abutment sheets by means of a damping base with screws, and a disposable sleeve made of brittle, collapsing material, such as porcelain, is attached to the base, coaxially with the rod, with screws. the elastic part of the collapsing element is made in the form of at least three leaf springs placed between the stop sheets and the clamping element of the sleeve ipa with grooves for fixing one end of the spring, the second end of each spring is secured by means of hinges on the sheets, the stops and the springs are arranged with an inclination of about 15 ° ÷ 45 ° in the direction of elastic-damping element collapsing disposable.

Images