RU2177062C1 - Fireproof slick bar - Google Patents

Abstract

FIELD: environmental protection. SUBSTANCE: slick bar is used for confining outflow of oil and other inflammable pollutants on water surface. Slick bar is built of separate sections joined together and provided with floating member accommodating one or more water-absorbing layers. Slick bar is provided with external casing made in the form of compact spiral or wicker net of water-repellent wire brush. Floating member has separate sealed hard floats. Water-absorbing inner and water-repellent outer collars are inserted in junctions. Water-repellent fireproof wire brush is made of fire-resistant material such as glass fiber, carbon fiber, or other fiber whose melting point is maximum 1100 C. External casing is cylinder-shaped structure; compact spiral or wicker net of external casing is spaced apart through distance not greater than diameter of wire brush. EFFECT: reduced weight; enlarged functional capabilities and operating reliability. 3 cl, 4 dwg

Description

 The invention relates to the protection of the environment and is intended for the localization of emergency oil spills and other combustible pollutants on the water surface.

 Known bon, designed to hold a flammable pollutant on the surface of the water and consisting of a hollow floating element, expanding when applying heat, covered with a layer of heat-resistant water-absorbing material with a mesh coating, which ensures the absorption of water with the formation of fire-retardant water flow (US patent N 4645376, IPC E 02 B 15/04).

The disadvantages of this fence are:
- the presence of direct contact of the water-absorbing material with the burning mass of the substance, as a result of which (in the absence of absolute hydrophilicity of the material) capillary absorption of the burning substance into this layer is also possible, which can lead to a decrease in the thickness of the fire-retardant flow with damage to the boom under high temperatures;
- the large weight and rigidity of the boom sections, making it difficult to install them on water bodies;
- the possibility of damage to the hydrophobic material of the booms during transportation.

 These disadvantages are to some extent eliminated in the known design of fire-resistant booms (US patent N 4537528, IPC E 02 B 15/04), which consists of a number of sections interconnected. Each section includes a float element made of separate chambers, on the outside of which there are several layers of water sorbing material, which performs the function of an osmotic wick having a shutter, which is a continuation of the water sorbing material, with a power element located in its lower part, which prevents direct contact of the inner surface hydrophilic layer with oil.

The disadvantages of this fence are:
- heavy weight, which complicates the transportation and deployment of barriers in water bodies;
- low operational reliability due to the fact that when the boom is bent due to the influence of water pressure or mechanical deformation of the boom under the influence of the wave effect, the internal suction layer is compacted, which reduces the osmotic absorption rate, which can lead to local burn-through of the shells and failure of the boom ;
- insufficient level of versatility of booms, limiting their use only in conditions of deep-water reservoirs, and the impossibility of using barriers in winter conditions.

 The objective of the present invention is to reduce the weight of fire-resistant booms, increasing its versatility and operational reliability.

 The solution to this problem is achieved by the fact that a fire-resistant boom barrier, consisting of interconnected sections, each of which contains a float element, on the outside of which one or more layers of water sorbing material are located, according to the invention is equipped with an outer shell, which is made in the form of a dense spiral or wicker nets of a hydrophobic fire-resistant ruff, and the float element consists of separate sealed solid-state floats, while the junction points of the sections are equipped with a hydrophilic morning and a hydrophobic outer cuffs.

Hydrophobic fire-resistant ruff can be made of heat-resistant material, such as fiberglass, carbon fiber or other fibers with a melting point of at least 1100 ^o C.

 Preferably, the outer shell has a cylindrical shape, and a dense spiral or braided mesh of the outer shell is made with a step not exceeding the diameter of the ruff.

The combination of features in this technical solution, including the presence of "one or more layers of water-sorbing material" with an additional "outer shell of a hydrophobic fire-resistant ruff", allows you to create in the boom, in contrast to the known, not two protective zones, but five: a capillary rise zone and a zone of vaporization (temperature 100 ^o C) with the implementation in them of the cooling effect due to the endothermic process of capillary circulation and evaporation of water; additionally, an oil absorption zone with a rise above the water surface and a zone of sublimation of oil vapor (temperature up to 400 ^o C) with the implementation of the cooling effect in them due to the endothermic process of capillary circulation and evaporation of hydrocarbons; as well as the zone of low-temperature combustion of oil vapor (temperature up to 750 ^o C), which separates the surface of the booms from the high-temperature region of oil combustion (temperature 110-1300 ^o C).

 At the same time, the simultaneous presence of these five zones with thermal protection mechanisms of various nature in combination with the proposed device of the outer shell, namely, made in the form of a spiral or wicker net made of ruff, allows for bending of the booms, which are possible due to water pressure or their mechanical deformation under the influence wave effect, eliminate excessive compaction of the internal hydrophilic and external hydrophobic layer and stabilize the intensity of the capillary rise of coolants, which prevents schaet emergence of local focal burn-through membranes, increasing the operational reliability of the boom.

 This set of features, given the presence of primary surface protection, makes it possible to manufacture hydrophilic (inner) shells from non-heat-resistant materials, which, combined with the implementation of the outer shell in the form of a tight spiral or woven mesh that reduces the consumption of heavy fire-resistant materials, significantly reduces the weight of the proposed fire-resistant boom.

 The combination of such features as the presence of an outer shell of a hydrophobic fire-resistant ruff and its cylindrical shape allows not only to expand the range of landscape conditions for the use of this fire-resistant barrier, including shallow water bodies, grass and moss swamps, but also determines the formation of the proposed boom barrier with a fleecy surface having sorption activity, which allows them to be used not only to retain the oil film, but also to clean the reservoirs from oil pollution.

This invention also provides an extension of the possible range of temperature conditions of use. So, in winter conditions, when ice is formed in the capillary structures of hydrophilic layers, the primary thermal protection of the boom in the described barrier is performed by a hydrophobic shell, which allows the booms to be operated in the mode of periodic freezing into the ice cover, which is typical for operation at ambient temperatures from 0 to -40 ^o C.

 The aforementioned expansion of the spectrum of landscape conditions for functional purposes and temperature conditions of application significantly increase the versatility of the proposed fire-resistant boom.

 The invention is illustrated by drawings, where figure 1 shows a General view of the boom; figure 2 is a section bb in figure 1, figure 3 is a section bB in figure 1; figure 4 is a section aa in figure 1.

Fire-resistant boom consists of cylindrical sections 1, which are interconnected by means of fire-resistant connections 2. The final sections of the boom are equipped with traction arms 3 with tension cables 4. Inside the section 1 of the boom along its longitudinal axis is a float element consisting of separate sealed solid-state floats 5. On top of the float element is a layer of hydrophilic material 6 and a hydrophilic elastic mesh shell 7. The outer shell 8 is made in the form of a dense with irali or woven mesh of a hydrophobic ruff flame retardant, as a material whose heat-resistant materials are used such as glass fiber, carbon fiber or other fiber having a melting point of not less than 1100 ^o C.

 Fire-resistant connections 2 are made in the form of connecting traction cables 9 with carabiners 10 on the outer surface of the extreme float 5, protected by a hydrophilic inner cuff 11, which is a continuation of the hydrophilic shell, and an external hydrophobic removable cuff 12. Fire-resistant connection 2 provides a tight connection of individual sections 1 into a single barrier .

 Fire-resistant boom works as follows.

 A fire-resistant boom barrier is delivered to the deployment site in transport pallets or drums, where the booms are laid using special technology. The deployment of the boom is carried out by pulling its extreme section for the cable 4 from the pallet by a boat, and the high tensile strength of the boom boom and the cylindrical shape of the boom optimal for this process allow this operation to be carried out with minimal time.

 In the conditions of high-speed rivers, it is advisable to install boom barriers as the first or second line for holding emergency oil and oil products spills in the form of a single string at an angle to the direction of water movement and for their simultaneous protection of the coastal zone at a distance from the coastal strip providing fire-fighting requirements, with their fixation position through winches. In conditions of low-flow and low-flow reservoirs, the most appropriate is the annular (closed) form of the location of booms.

 Fixing the position of booms in water bodies is carried out by means of special buoys or winches with heat-resistant cables.

In the event of the ignition of oil or other combustible materials, the latter, upon contact with the hydrophobic shell 8, are absorbed into it and rise along the surface of the ruff threads into the zone located above the surface of the water, where the endothermic process of sublimation of its vapor occurs. The burning of oil vapor is noted above the fleecy surface of the ruff (boom), while the hot ends of the thread are elements that support the stability of the combustion process. Due to this process, the temperature inside the hydrophobic shell 8 does not exceed 400 ^o C and is a natural protective zone that prevents burning of the surface of the boom. The layer of hydrophilic material 6 and the hydrophilic elastic mesh shell 7 of the float element carry out capillary absorption of water, the evaporation of which occurs above their surface, protecting the float element from thermal effects, while water vapor entering the evaporation zone of oil products reduces the overall combustion temperature on the surface of the boom .

 After the operation of fire-resistant booms, their transportation and delivery to the storage place are carried out in transport pallets. The regeneration of the surface shell of booms with its purification from residual oil products and oil combustion products is carried out by controlled combustion or by a reagent method, depending on the residual pollution of the booms.

 Thus, the proposed fire-resistant boom barrier allows you to quickly hold and concentrate the emergency spill of oil and oil products in the conditions of their spontaneous combustion. The proposed fire-resistant boom barrier is universal, has increased operational reliability, is convenient for transportation and deployment in water bodies due to its light weight and cylindrical shape.

Claims (3)

 1. Fire-resistant boom barrier, consisting of interconnected sections, each of which contains a float element, on the outside of which there are one or more layers of water-sorbing material, characterized in that it is provided with an outer shell, which is made in the form of a dense spiral or woven mesh of hydrophobic fire-resistant ruff, and the float element consists of separate sealed solid-state floats, while the junction of the sections is equipped with a hydrophilic inner and hydrophobic outer cuffs. 2. The fence according to claim 1, characterized in that the hydrophobic fire-resistant ruff is made of a heat-resistant material, such as fiberglass, carbon fiber or another fiber with a melting point of at least 1100 ^o C.  3. The fence according to claim 1 or 2, characterized in that the outer shell has a cylindrical shape, and a dense spiral or braided mesh of the outer shell is made with a step not exceeding the diameter of the ruff.

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