RU2713685C1 - Flame-explosion-proof structure of guard against action of dangerous fire factors - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction, in particular to erection of enclosures on objects of high explosive and fire hazard, including those located in places of mass congestion of people and dense urban development, and can be used in gas stations of various purposes and storage facilities of hydrocarbon fuel. Flame-explosion protection design of the enclosure against fire hazards consists of a protective shield having cylindrical curvature. Screen is made of a set of metal expanded and drawn sheets laid on each other with shift in staggered order, providing formation of chaotic slots in screen with equivalent cross-section diameter of 2–8 mm, wherein sheet perforation has flake structure, slots of which face towards movement of shock wave or heat flow. Screen is rigidly attached to reinforced concrete or metal supports mounted on the foundation. Screen is directed inward towards the shock wave or heat flow, so that the angle of inclination of the lower part of the screen is close to the horizon, and then the screen is curved to the upper part at right angle to the horizon.

EFFECT: invention allows improving reliability of population and infrastructure protection against fire and explosion wave hazard factors.

1 cl, 2 dwg

Description

The invention relates to the construction, in particular, to the construction of fences at facilities of increased explosion and fire hazard, including those located in crowded places and dense urban areas, and can be used at gas stations for various purposes and hydrocarbon fuel storage facilities.

Known fire wall (RF patent No. 2260658 class Е04В 1/94 dated 04/20/2004) made in the form of a structure including reinforced concrete columns, three-layer panels with a core of non-combustible mineral wool, attached to the columns with an overlap using fasteners.

The disadvantage of this invention is not the high reliability of the fire wall from fragmentation and the effects of waves of excess pressure during the explosion. The vertical design of the fire wall creates the effect of reflecting the damaging effect from dangerous fire factors and will increase the risk of death and destruction of objects located on the inside of the structure. The design of the fire wall does not comply with the fire safety requirements for gas stations and hydrocarbon fuel storage facilities, in particular, it does not provide a sweep of the territory.

The closest in technical essence and the achieved effect is a device for protecting the structure from the shock wave (RF Patent No. 2226342 class F42D 5/045, ЕНН 9/00 of 07/11/2006), which consists of a protective shield made in the form of a plate having a non-spherical curvature, for example, cylindrical, and a curved surface, for example, wavy. The plate is installed with the inner side of the curvature facing the shock wave and placed between the foundation and the supporting wall fixed on the foundation. The outer side of the plate facing the wall is fixed to it by a series of compression springs, and the outer side of the plate facing the foundation freely rests on a movable support, for example, a pipe placed on the foundation. The device allows for protection against the destructive action of the shock wave.

The disadvantages of this invention include weak scattering and reflection inside the enclosure of a portion of the thermal radiation during the implementation of various types of fire due to the absence of fire-blocking elements on its surface. Under the directed effect of flaring, the design does not provide for the dispersion and absorption of part of the thermal effect, compression springs will suffer especially quickly, which will lead to loss of bearing capacity. The device does not comply with the fire safety requirements for gas stations and hydrocarbon fuel storage facilities, and does not provide a sweep of the territory.

In the known device for protecting the structure from the shock wave, the protective screen does not allow the extinguishing of the flame falling on the device, and intensive heat exchange between the burning vapor-gas flow and the internal structure of the screen. As a result, the temperature of the burning vapor-gas-air flow of the mixture will not decrease, and part of the thermal radiation reflected from the protective screen will have a destructive effect on objects and on the life and health of people on the inside of the structure.

The technical task of the claimed invention is to increase the reliability of protecting the population and infrastructure from the effects of dangerous fire factors at hydrocarbon fuel storage facilities that can withstand both an explosion consisting in the propagation of a shock wave of destructive action and high-energy fragments, and the temperature effect of various types of hydrocarbon fuel fire: flaring , fire-strait, fireball; ensuring compliance with fire safety requirements for gas stations and hydrocarbon fuel storage tanks, in terms of the design of the fence.

The technical task of the invention is achieved in that the flameproof design of the enclosure against the effects of hazardous fire factors includes a foundation; reinforced concrete or metal supports withstanding the loads of a possible maximum design basis accident; according to the invention, the protective shield of the flame-explosion-proof construction is made of a set of metal expanded metal sheets laid on top of each other with a staggered pattern, which ensures the formation of chaotic curvature of a cylindrical curvature, the inner side facing the shock wave channels in the screen with an equivalent cross-sectional diameter of 2 ... 8 mm, while the perforation of the sheets has a scaly structure, the slits of which are reversed us forward motion of the shock wave or heat flux.

The technical result consists in the absorption and dispersal of part of the energy of the shock wave or heat flux by a protective shield, which ensures the protection of people and infrastructure from the outside of the structure and the reduction of the effects of dangerous fire factors from the inside of the structure. Flameproof explosion-proof fencing design made of perforated non-combustible materials provides blowing through the territory, which meets the fire safety requirements for gas stations and hydrocarbon fuel storage facilities.

A schematic representation of a flame-explosion-proof design of a barrier against the effects of dangerous fire factors is shown in FIG. 1 and in FIG. 2 is an enlarged image of B in FIG. 1.

Flameproof explosion-proof design of the fence from the effects of hazardous fire factors consists of a protective shield 1 having a cylindrical curvature. The screen 1 is made of a set of metal expanded metal sheets with a thickness of b (Fig. 2), stacked on top of one another with a staggered offset, ensuring the formation of random gaps in the screen with an equivalent section diameter of 2 ... 8 mm, while the perforation of the sheets has a scaly structure, the slots which are facing the movement of the shock wave or heat flux (Fig. 1, view A). The screen 1 is rigidly attached to reinforced concrete or metal supports 2 mounted on the foundation 3. The design of reinforced concrete or metal supports 2 and the foundation 3 must withstand the loads of the maximum possible design basis accident.

The screen 1 faces the interior of the shock wave or heat flow, so that the angle of inclination of the bottom of the screen is close to the horizon, providing a uniform approach of the pressure wave, high-energy fragments or heat flow to the structure and then the screen is curved to the top at a right angle to the horizon , providing dispersion of pressure waves, high-energy fragments or heat flux in the atmosphere, as well as partial absorption of their energy inside the protective shield.

The design works as follows.

In the explosion of a vapor-gas cloud, the pressure wave, in contact with the protective shield 1, partially penetrates into the structure due to the opposite direction of the slots in the metal expanded metal sheets, as shown in FIG. 1. Randomly located channels formed by a set of expanded metal sheets laid on top of each other contribute to the crushing and quenching of a significant part of the energy of the air wave, transforming it into a smooth gas-dynamic flow from the outside of the structure, which does not pose a danger to the protected objects, human life and health. Part of the air wave that does not penetrate the protective shield passes along its inner side and is scattered in the atmosphere at right angles to the horizon.

In the event of flaring and a fire-strait aggravated by gusts of wind, the flame-explosion-proof design of the enclosure from the effects of hazardous fire factors will operate in a flame arrester mode. A part of the heat flux directed towards the fence will be absorbed into the protective shield 1 due to the onward direction of the slots in the metal expanded metal sheets, as shown in FIG. 2. The flame passing through the channels of a small cross-sectional area, formed by a set of expanded metal sheets laid on top of each other, will be crushed into small parts. Intensive heat exchange occurs between the vapor-gas flow and the walls of narrow channels. Due to this, the temperature of the gas-vapor flow decreases sharply and the flame is extinguished until it reaches the outer surface of the protective screen. During detonation combustion, the narrow channels of the shield 1 crush the front of the shock wave. That part of the heat flux that has not penetrated into the protective shield 1 passes along its inner side and is scattered in the atmosphere at right angles to the horizon.

When exposed to high-energy fragments generated during the explosion of equipment on the flame-explosion-proof design of the enclosure from the effects of dangerous fire factors, the protective shield 1 will perform a damping function. When high-energy fragments approach the inner surface of the protective shield at an angle close to the right angle, metal expanded metal sheets will be squeezed into each other due to the free space of the channels existing in them, absorbing a significant part of the kinetic energy of the fragments, excluding their rebound from the fence back side. When high-energy fragments approach the inner surface of the protective shield tangentially, they will pass along its inner side, losing their destructive force due to increased friction on the rolled fiber of expanded metal sheets facing the movement of the fragments.

In accordance with current recommendations [GOST R 12.3.047-2012 Occupational safety standards system. Fire safety of technological processes. General requirements. Control methods] the critical diameter of the flame-extinguishing elements, for example, 2.6 mm can be selected for propane, then the recommended channel length should be at least 260 mm. Such values when implementing the design of flame-explosion protection from the effects of hazardous fire factors can be achieved using expanded metal sheets, for example, markings

in accordance with TU 36.26.11-5-89 "Expanded steel sheets. Specifications ”, laid on each other with a staggered offset, ensuring the formation of chaotic channels with an equivalent diameter of 2.6 mm ± 1 mm, in the amount of 16 pieces, forming a protective shield 267 mm thick.

The strength of reinforced concrete or metal supports and foundations can be calculated by the value of the explosion overpressure from the conditions of the maximum design basis accident. For example, when a liquefied hydrocarbon gas leaks from a storage tank with a volume of 20 m ³ , the supports installed on the foundation of the flame-explosion-proof construction of the barrier from the effects of dangerous fire factors, located at a distance of 20 m from the explosion epicenter, must withstand an overpressure of the gas-air mixture in the amount of 83.4 kPa [Determination of fire risk values at production facilities for storage of liquefied petroleum gas [Text]: study guide / Shevtsov SA, Kargashilov DV, Vogman LP .. - Voronezh: Publishing House ligrafichesky Center "Science Book", 2018. - 89 c]..

The air ducts in the protective screen formed by stacking expanded tiles on each other in a checkerboard pattern will ensure that the territory inside the enclosure is blown out, excluding the unpredictable formation of explosive fire-hazardous gas-vapor accumulations, which meets the fire safety requirements for gas stations and facilities hydrocarbon fuel storage.

Thus, the proposed flame-explosion-proof design of the guard against the effects of dangerous fire factors provides effective protection of people and infrastructure from the outside of the protective shield and reduces their impact from the inside of the protective shield, eliminating the reflective effect. The design allows you to:

- resist the propagation of a pressure wave from an explosion of a vapor-gas cloud by crushing and extinguishing one part of it, turning it into a smooth gas-dynamic flow, and dispersing the other part into open space;

- to extinguish the directed flame during the implementation of various types of fires with the redirection of part of the heat flux into the open space;

- perform a damping function when exposed to high-energy fragments generated during the explosion of equipment, absorbing their kinetic energy inside the structure due to crushing of the protective screen or directing the trajectory of their movement into open space;

- comply with fire safety requirements for the fencing of gas stations and storage facilities for hydrocarbon fuel, ensuring the blowing of their territories due to the presence of air channels in the protective screen.

Claims (1)

Flameproof explosion-proof fencing design from the effects of dangerous fire factors, including the foundation; reinforced concrete or metal supports withstanding the loads of a possible maximum design basis accident; a protective screen of cylindrical curvature facing the inside of the shock wave and rigidly attached to reinforced concrete or metal supports with the external side, characterized in that the protective shield of the flameproof design is made of a set of metal expanded metal sheets laid on each other with a staggered offset, providing the formation of chaotic channels in the protective screen with an equivalent cross-sectional diameter of 2 ... 8 mm, while the perforation of the sheets has a scaly structure, cuts which s face opposite to the motion of the shock wave or heat flux.

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