RU2558820C1 - Explosion-proof damaged structure of building enclosure by kochetov - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: in a safety damaged structure of an enclosure, comprising reinforced concrete panels with size of 6000×1800 mm, the panel consists of damaged and non-damaged parts, at the same time the non-damaged part is made in the form of bearing ribs placed along the contour of the damaged part, and the damaged part is made in the form of at least two coaxially arranged grooves in a building wall, one of which, the external one, is formed by planes of regular quadrangular truncated pyramid with a rectangular base, and the other one, the internal one, represents two inclined surfaces connected with a rib to form a slot. Thickness of the wall from the rib to the external surface of the building enclosure must be at least δ=20 mm. Under exposure of impact explosive load this area of the wall may be divided into separate parts, and opposite to the damaged part, at the outer side of the building enclosure, there is a protective screen from high-strength material, for instance, armour-piercing material, which is fixed on at least three horizontally arranged rods perpendicular to the building enclosure, at the ends of which there are discs fixed, and which pass through the holes in the protective screen, besides, discs arranged at the right side of rods are embedded into building enclosures, and elastic elements at the left side of the rods rest against the discs, and such elastic elements support the protective screen to the enclosure of buildings.

EFFECT: increased reliability of actuation of damaged explosion-proof devices in case of an emergency explosion at a facility.

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Description

The invention relates to protective devices used in explosive objects, such as easily removable panels and roofs, explosion-proof fences and dampers, overpressure valves.

A device for explosion-proof panels is known (application DE No. 19638658, IPC Е04В 1/92 dated 04/16/1998), where the possibility of raising and lowering the panel to its original place in the explosion is carried out by the action of springs inserted into the support pipes.

The closest technical solution to the claimed object is the explosion-proof collapsing design of the fence according to the patent of the Russian Federation No. 131757, Cl. Е04В 1/92 (prototype), containing reinforced concrete panels of 6000 × 1800 mm in size, and the panel consists of collapsing and non-collapsing parts, while the non-collapsing part is made in the form of load-bearing ribs placed along the contour of the collapsing part, and the collapsing part is made in the form of at least two coaxially located recesses in the wall of the building, one of which, the outer one, is formed by the planes of a regular quadrangular truncated pyramid with a rectangular base, and the other, the inner one, is two inclined surfaces and, connected by an edge, with the formation of a groove, while the wall thickness from the edge to the outer surface of the building fence must be at least δ = 20 mm, while under the influence of shock, explosive load this section of the wall can be divided into separate parts, and the area collapsing part of the openings is calculated by the formula:

,

,

where V _o - the free volume of the room, m ³ ; α is the combustion intensification coefficient; w _n is the normal flame propagation velocity in a mixture of stoichiometric composition, m / s; ρ is the density of gases flowing from the openings, kg / m ³ ; ε is the degree of thermal expansion of the combustion products; Δр _extra - permissible pressure in the room (5 kPa), and opposite the collapsing part, on the outside of the building’s fence, there is a protective shield made of high-strength material, such as armored material, which is fixed to at least three horizontally located and perpendicular to the building’s fencing rods, at the ends of which the disks are fixed and which pass through the holes in the protective shield, the disks located on the right side of the rods are walled up in the fencing of the building, and in the disks on the left side of the rod it rests against elastic elements supporting the protective screen to the enclosure of buildings.

A technically achievable result is an increase in the reliability of the operation of collapsing explosion-proof devices during an emergency explosion at the facility.

This is achieved by the fact that in the explosion-proof collapsing structure of the enclosure containing reinforced concrete panels of 6000 × 1800 mm in size, the panel consists of collapsing and non-collapsing parts, while the non-collapsing part is made in the form of load-bearing ribs placed along the contour of the collapsing part, and the collapsing part is made in the form at least two coaxially located recesses in the wall of the building, one of which, the outer one, is formed by the planes of a regular quadrangular truncated pyramid with a rectangular base, and others The corner, inner, is two inclined surfaces connected by a rib to form a groove, while the wall thickness from the rib to the outer surface of the building enclosure should be at least δ = 20 mm, while under the influence of shock, explosive loading this wall section can be divided into separate parts, and opposite the collapsing part, on the outside of the building’s enclosure, there is a protective shield made of high-strength material, such as armor-piercing material, which is fixed to at least three horizontally distributed rods lying and perpendicular to the building barrier, at the ends of which the disks are fixed and which pass through the holes in the protective shield, the disks located on the right side of the rods are walled up in the building enclosures, and the elastic elements supporting the protective screen against the disks on the left side of the rods fencing of buildings.

In FIG. 1 shows a general diagram of an explosion-proof collapsing structure of a building enclosure; FIG. 2 is a diagram of an arrangement of a protective screen; FIG. 3 - the nature of the change in pressure Δp from time τ during the combustion of combustible mixtures indoors, in FIG. 4 is a diagram of a one-time shock absorber with collapsing elements, FIG. 5 is an embodiment of a one-time shock absorber with collapsing elements.

Explosion-proof collapsing fencing structure (Fig. 1) of phononless buildings (organized collapsing structure - ORK), in which there are no window openings, consists of reinforced concrete panels 1 with a size of 6000 × 1800 mm. The panel consists of collapsing and non-collapsing parts. The nondestructive part is made in the form of bearing ribs 9 (200 × 150 mm), placed along the contour of the ORC. The collapsing part is made in the form of at least two coaxially located niches (recesses in the wall of the building), one of which, the outer one, is formed by the planes 2, 3, 4, 5 of the regular quadrangular truncated pyramid with a rectangular base, and the other, the inner one, represents two inclined surfaces 6 and 7 connected by a rib 8 to form a groove, while the wall thickness from the rib 8 to the outer surface of the building enclosure should be at least δ = 20 mm. Due to these grooves in the wall of the building under the influence of shock, explosive load, this section of the wall can be divided into separate parts. The collapsing parts of the panel in the grooves are connected by fittings (not shown in the drawing) in such a way that the plates do not deform during transportation, installation and wind load.

Opposite the collapsing part, on the outside of the building’s enclosure, there is a protective shield 10 (Fig. 2) made of high-strength material, such as armored material, which is fixed to at least three horizontally located and perpendicular to the building’s enclosure rods 11, at the ends of which are fixed disks 12 and 13 and which pass through holes 14 made in the protective shield, the disks 13 located on the right side of the rods being walled up in the fencing of the building, and in the disks 12 located on the left side of the rod 11, abut the resilient elements 15, holding up the shield 10 to the enclosure buildings.

The recesses in the wall of the building (niche), one of which, the outer one, is formed by the planes 2, 3, 4, 5 of a regular quadrangular truncated pyramid with a rectangular base, and the other, the inner one, is two inclined surfaces 6 and 7, connected by an edge 8, can be filled with heat and sound absorbing material 16 and closed with a decorative panel that is easily destroyed by explosion 17.

A disposable shock absorber with collapsing elements (Fig. 4) comprises a rod 11 to which a disk 12 is rigidly fixed, to which a damping base 18 is attached with screws 19. To the damping base 18, coaxially to the rod 11, an elastic sleeve 20 made in the form of a truncated cone is rigidly attached , for example, made of polyurethane, and the lower base of the truncated cone is connected with the damping base 18, and the upper abuts against a one-time action element made in the form of a sleeve 21 from a brittle, crumbling mat iala, for example porcelain, which is pressed by an elastic element 15, made in the form of a conical spring, facing with its large base towards the disk 12, and lower towards the protective screen 10, where it is fixed in the grooves 22 made in the protective screen 10, by means of injection polyurethane .

A variant is possible (Fig. 5) when the disposable action element 23 is made in the form of a sleeve of brittle, collapsing material, such as porcelain, and is located coaxially to the rod 11, covers an elastic element 15 made in the form of a conical spring, while one end of the sleeve abuts into the protective shield 10, and the other into the disk 12, and the sleeve 21, located between the screen 10 and the elastic sleeve 20 in the form of a truncated cone of polyurethane, is made elastic.

Assembly of a single-acting shock absorber with collapsing elements is carried out in the following sequence. A disk 12 is welded to the rod 11, perpendicular to its axis, after which a damping base 18 is attached to it with screws 19 having grooves (not shown in the drawing) for installing a larger base of the conical spring 15, which is filled with injection molded polyurethane. After that, an elastic sleeve 20 made of polyurethane and a sleeve 21 made of a brittle, collapsing material, which is pressed by a protective shield 10 by means of a conical spring 15, are installed on the rod 11.

Explosion-proof collapsing construction of buildings works as follows.

For most gas-air mixtures (DHW), the maximum explosion pressure in a closed volume p _max at µ = 1 is 0.7 ÷ 1.0 MPa, i.e. 6 ÷ 9 times higher than atmospheric pressure (Fig. 3). Such pressure creates a load significantly exceeding the bearing capacity of structures (walls, floors) of industrial buildings. Obviously, such a lot of pressure should not be allowed. To do this, when developing a production project, openings are provided. In FIG. Figure 2 shows the nature of the change in pressure Δp versus time τ during the combustion of combustible mixtures indoors: Δr _vsk - pressure that causes the opening of safety structures (PC); Δp _add - allowable pressure in the room (Δp _add = 5 kPa); 1 - dynamics of pressure changes for rooms with openings; 2 - pressure change dynamics for rooms with a PC.

Consider the main scenarios leading to the ignition of combustible systems (HS) for compressed gases - depressurization of equipment with the formation of gas-air mixtures; for LVH - emergency liquid spill with formation of vapor-air mixtures; for dusts - dust accumulation on the surfaces of structures and equipment with the formation of dusty air mixtures.

In practice, safety structures are widely used to divert energy during combustion. For this, it is necessary to have such a number of holes in the disturbed building envelopes that would allow the passage of the required amount of both burnt and cold gas. These holes are usually called discharge, and the structures that enclose them are called safety structures (PC). The safety structures are opened at a relatively small excess pressure and thereby provide the possibility of intensive outflow of gas (combustion products and unreacted parts of the gas supply system) through the formed openings from the room to the outside atmosphere. The outflow of gas into the atmosphere leads to a decrease in overpressure in the room. The degree of pressure reduction depends on the area of the PC, the patterns of their opening, the type of HS, the nature of the gas contamination of the room, its space-planning solution, and other factors. A very interesting application as a PC was glass, glazing. Glasses used as PCs can be installed both in the walls of the building (in the form of glazed window frames) and in the lanterns (lantern superstructures) mounted on the roof of the structure. In the latter case, not only vertical glazing can be used, but also inclined and horizontal glazing. The formation of openings in glazed window frames and lanterns (lamp superstructures) occurs as a result of the destruction of glasses under the influence of excess pressure arising in the room during explosive burning of gas. The patterns of opening the glazing largely depend on the size of the glass, their thickness, fixing conditions and the type of glazing (single, double or triple).

There are PC solutions in the form of lightweight drop-down wall panels. These panels are attached to the building frame in such a way that, at a relatively small excess pressure that occurs in the room during explosive combustion of the horizontal structure, the fasteners are destroyed and the panels are separated from the frame. As a result of the dumping of wall panels, a certain part of the external enclosure of the room is eliminated. In the coatings of the building, PCs can be arranged in the form of lightweight slabs that overlap the previously provided openings. The release of these openings is carried out as a result of lifting the plates under the action of the load arising from the explosive combustion of the horizontal well. Organizable collapsing structures (ORCs) are of considerable interest. Autopsy of ORCs occurs as a result of the destruction of plates during explosive combustion. The destruction of the plates occurs in the placement of special grooves. The thickness of the concrete layer in the groove is δ = 20 mm. Under the influence of loads, the considered types of ORK are quickly destroyed, without forming debris, they retain heat well in heated buildings and are manufactured using existing ORK technological equipment, they are reinforced concrete panels measuring 6000 × 1800 mm.

The shock absorber disposable with collapsing elements (Fig. 4) works as follows.

From the action of the shock wave, the shield 10 begins to compress the conical spring 15. With the further movement of the shield 10, it destroys the disposable sleeve 21 made of brittle, collapsing material, such as porcelain, and compresses the sleeve 20 in the form of a truncated cone, which acts as a damper, as well as a conical spring 15, and then interacts with the damping base 18. In the case of a large (more than 5 KPa) pressure of the blast wave, either the welding joint that attaches the rod 11 to the disk 12 is cut off, a blockage occurs and a break rod 11, which also helps to reduce the damage.

In the second embodiment (Fig. 5), from the action of the shock wave, the protective shield 10 destroys the one-time action element 23 made of brittle, collapsing material, such as porcelain, and located between the protective shield 10 and the disk 12, and then begins to compress the conical spring 15.

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 (1)

Explosion-proof collapsible building enclosure structure containing reinforced concrete panels of 6000 × 1800 mm in size, the panel consists of collapsing and non-collapsing parts, while the non-collapsing part is made in the form of load-bearing ribs placed along the contour of the collapsing part, and the collapsing part is made in the form of at least two coaxially located recesses in the wall of the building, one of which, external, is formed by the planes of a regular quadrangular truncated pyramid with a rectangular base, and the other, internal, it consists of two inclined surfaces connected by an edge, with the formation of a groove, while the wall thickness from the edge to the outer surface of the building fence must be at least δ = 20 mm, while under the influence of shock, explosive load this wall section can be divided into separate parts , and the area of the collapsing part of the openings is calculated by the formula:

,
where V _o - the free volume of the room, m ³ ;
α is the coefficient of intensification of combustion;
w _n - normal flame propagation velocity in a mixture of stoichiometric composition, m / s;
ρ is the density of gases flowing from the openings, kg / m ³ ;
ε is the degree of thermal expansion of the combustion products;
Δp _add - allowable room pressure (5 kPa),
and on the contrary to the collapsing part, on the outside of the building’s enclosure, there is a protective shield made of high-strength material, such as armored material, which is fixed to at least three rods horizontally located and perpendicular to the building’s enclosure, at the ends of which the disks are fixed and which pass through the holes in the protective screen, and the disks located on the right side of the rods are walled up in the fencing of the building, and the elastic elements supporting the protection abut against the disks on the left side of the rods a solid screen to the enclosure of buildings, and recesses in the wall of the building, one of which, the outer one, is formed by the planes of a regular quadrangular truncated pyramid with a rectangular base, and the other, the inner one, is two inclined surfaces connected by an edge, filled with heat and sound absorbing material and covered with decorative, easy a panel that collapses during an explosion, characterized in that the single-acting element is made in the form of a sleeve of a brittle, collapsing material, such as porcelain, and is located coaxially The elastic element is made in the form of a conical spring, and one end of the sleeve abuts against the protective shield and the other into the disk, and the sleeve located between the screen and the elastic sleeve in the form of a truncated cone made of polyurethane is made elastic.

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