RU2660010C1 - Emergency situation simulation test bench - Google Patents

Abstract

FIELD: safety systems.

SUBSTANCE: invention relates to safety systems preventing development of emergency situations. In the emergency situation simulation test bench, containing installed on the posts explosive facility mock-up, with the explosion initiator installed therein, 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, explosive facility mock-up is equipped with the examined on the test bench facility: installed above the hole in the mock-up upper part explosion-proof element, which consists of armored metal frame with armored metal lining and the lead filler, 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: increase in the process equipment and human resources protection against emergencies efficiency due to the possibility to predict the emergency situations development in case of accident at the explosive facility.

3 cl, 3 dwg

Description

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

The closest technical solution to the claimed object is the emergency safety device according to the patent of the Russian Federation No. 120569, А62С 35/00, dated March 20, 12 (prototype), containing a system of elements installed in the danger zone of the protected object, which must be transferred from normal operation in emergency mode as a result of the danger of 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 an emergency modeling booth containing 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 hazardous 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 of the rubber and percale layers, the model of an explosive object is equipped with the object studied at the stand: an explosion-proof element mounted above the hole in the upper part of the model, which consists of an armored metal frame with armored metal casing and lead filler, and in the upper part of the model, at the hole, symmetrically about its axis, four support rods are embedded that are telescopically inserted into fixed support pipes embedded in the panels of the explosion-proof element, and for fixing the maximum on the position of the panel, stop plates are welded to the ends of the support rods.

In FIG. 1 shows a schematic diagram of a stand for modeling an emergency in an accident at an explosive facility, FIG. 2 is a diagram of an explosion-proof element; FIG. 3 is a diagram of an elastically damping support rod.

The stand for modeling an emergency in an accident at an explosive facility contains a model 1 of an explosive hazardous facility 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 layout 1 explosive facility located in the test box 6. In addition, the layout 1 is equipped with a transport 7 and suspension 8 systems, and the protective cover 4 is multilayer and consists of facing inward to the layout 1 a yuminievogo layer, and then the rubber perkalevogo 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.

Elastic-damping elements 16 can be made in the form of cylindrical coil springs, the external helical surface of which is covered with vibration-damping mastic, for example, type VD-17.

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.

Stand for modeling emergency works as follows.

In test box 6 set the layout 1 of an explosive object. In the upper (ceiling) part of the layout 1, a hole 10 (aperture) is made, which is closed by an explosion-proof element 9 installed in a loose fit on the three support rods 13, 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 in the form of stop sheets 15. After the initiator of the explosion 3 is triggered, an analysis of the situation is carried out, after processing the received experimental data, an information database on the development of an emergency in an accident at an explosive facility and ulation mathematical model predictive emergency prevention at the hazardous facility accident.

Explosion-proof element 9 operates as follows.

In an explosion 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, extinguishing the energy of the explosion, and then return the panel 9 to its original state.

The outer helical surface of the elastically 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. The stop sheets 15 are used to fix the limit position of the panel. 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 a crumb, and the support rods 13 can be made resilient.

The elastic-damping support rod 13 (Fig. 3) is a cylindrical damping element with a cylindrical shell, to the ends of which are rigidly fixed flat stops: the top 15 and bottom 24, rigidly sealed in the cover of the layout 1 at the opening 10. The bottom 24 stop is made reinforced with at least three triangular jibs 27 rigidly connected to the cylindrical shell 28 and the lower stop 24, for example by welding.

The inner cavity of the cylindrical shell 28 is filled with a set consisting of at least two damping disks: the upper 20 and lower 21, mounted on the elastic axis 19, coaxially located with the cylindrical shell 28, of the cylindrical damping element. Moreover, the connection 18 of the elastic axis 19 with the upper 15 hard stop is made more durable than the connection 17 of the cylindrical shell 28 with the upper 15 hard stop. Between the damping disks of the upper 20 and lower 21 is located at least one coil spring 22, the cavity of which is filled with vibration damping material, for example polyurethane.

A cylindrical coil spring 22 is rigidly fixed by fasteners 23 to the upper 20 damping disk and by fasteners 25 to the lower 21 damping disk, which in turn is fastened by fasteners 26 to the cylindrical shell 28.

An embodiment of a hollow support rod is possible when the elastic axis 19, coaxially located with the cylindrical shell 28, is hollow, while the cavity is filled with vibration damping material, for example polyurethane.

Stand for modeling emergency works as follows.

In an explosion inside an industrial building (not shown in the drawing), the frame 11 rises with the armored metal casing 12 and the filler from the action of the shock wave, and overpressure is released through the open opening 10.

In the event of an emergency, increased overpressure inside the production room when the frame 11 is lifted, a “weak link” in the security system is triggered, which in the explosion protection device scheme being considered is the connection 17 of the cylindrical shell 28 with the upper 15 hard stop, which is broken, and the frame 11 with armored metal sheathing 12 and the upper 15 remaining on it with a hard stop, moving up along the guides, which are the outer surface of the cylindrical shell 28, a hollow-cylindrical damping element support bar moves upwards the elastic axis 19 together with the upper damping disc 20, thus stretching the spring 22 which at the bottom is fixedly secured to the lower damping disc 21, thereby reducing the energy of a blast wave.

The implementation of the support rods hollow allows you to damp skews when moving the frame 11 with armored metal sheathing 12 up from the action of the shock wave, as well as the unevenness of the overpressure released through the open opening 10.

After the explosion and the drop in excess pressure, dropping down, the frame 11 closes the opening 10, and harmful substances do not enter the atmosphere, and the explosion protection system is returned to its original position, restoring the broken connection 17 of the cylindrical shell 28 with the top 15 hard stop, which fulfilled its function of "weak link ”in the security system.

Using the proposed technical solution allows the prevention of explosive objects from destruction and the reduction of harmful substances into the atmosphere during an accidental explosion.

Claims (3)

1. A stand for modeling an emergency, containing a model of an explosive 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, as well as a rubber and percale layers, while the model of an explosive object is equipped with the object studied on the stand: an explosion-proof element installed above the hole in the upper part of the model, which consists of an armored metal frame with armored metal casing and lead filler, and in the upper part of the model, at the hole, symmetrically relative to its axis, four support rods are fixed, telescopically inserted into fixed support pipes, embedded in the panels of the explosion-proof element, and to fix the limit position of the panel whether stop sheets are welded to the ends of the support rods, characterized in that each of the support rods, telescopically inserted with the lower part into the fixed support pipes embedded in a metal frame, is hollow with a set of damping disks in the inner cavity. 2. A stand for modeling an emergency according to claim 1, characterized in that the hollow support rod is a cylindrical damping element with a cylindrical shell, to the ends of which are rigidly fixed flat stops: the upper and lower, rigidly sealed in the coating of the object at the opening, the lower stop is reinforced with at least three triangular jibs rigidly connected to the cylindrical shell and the lower stop, for example by welding, and the inner cavity is filled with a cylindrical shell and a set consisting of at least two damping disks: the upper and lower mounted on the elastic axis coaxially located with the cylindrical shell of the cylindrical damping element, while the connection of the elastic axis with the upper rigid stop is made more durable than the connection of the cylindrical shell with the upper at least one cylindrical helical spring, the placement cavity of which is filled with vibration damping material, is located between the upper and lower damping disks, for example, polyurethane, while the coil spring is rigidly fixed by fasteners to the upper damping disk and by fasteners to the lower damping disk, which in turn is rigidly connected to the cylindrical shell by fasteners. 3. The emergency simulator according to claim 2, characterized in that the elastic axis of the hollow support rod coaxially located with the cylindrical shell is hollow, while the cavity is filled with vibration damping material, for example polyurethane.

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