RU95684U1 - PERMANENT BUILDING BOAM BAG WITH SORBING SINKS - Google Patents

Abstract

 1. Boom boom of constant buoyancy, characterized in that it consists of at least one section of PVC fabric forming a float chamber, divided into at least five airtight compartments, each of which contains a cylindrical float made of polyethylene foam, and having a steel rope in the upper part for stiffening, a pocket with a ballast chain in the underwater part, two duralumin strips at the ends of each section for connecting them to each other, handles from webbing slings in the upper part for extracting the section and water and sorbing laths reusable for collecting oil, adapted to be attached to each section using plastic clamps with snap hooks. ! 2. The boom according to claim 1, characterized in that the float is made of sheet polyethylene foam, rolled up and welded at the edges. ! 3. The boom according to claim 1, characterized in that the handles are secured between the sealed compartments using a bolted connection. ! 4. The boom according to claim 1, characterized in that the steel rope is placed in a polyamide sheath. ! 5. The boom according to claim 1, characterized in that the pocket with a ballast chain is made in the form of a pipe and runs along the entire length of each section. ! 6. Boom barrier according to claim 5, characterized in that the pocket with a ballast chain has openings for air outlet and inflow / outflow of water. ! 7. The boom according to claim 1, characterized in that the sorbent pads are placed on the side of each section. ! 8. The boom according to claim 7, characterized in that the sorbent pads are a sorbent non-woven fabric, folded

Description

The utility model relates to the field of environmental protection, namely to the construction of permanent buoyant booms designed to localize oil and oil products spills and clean them from the water surface in port water areas, harbors, in isolated sections of coastal waters, rivers and other bodies of water with flow rates up to 1.5 m / s, wind speeds up to 7.9 m / s and the excitement of the water surface not more than 3 points.

A boom barrier (bon) is known from the prior art, which includes rectangular floats equipped with vertical screens of shell material and filled with an oil sorbent, interconnected by a flexible connection. Linen fabric is used as a shell of the floats, and a modified aero-fountain drying fiber is used as a sorbent - waste from pulp and paper production (RU 2287042, 10.11.2006).

The disadvantage of this boom is that, as oil products are absorbed, the floats with the sorbent gradually melt in water, at 100% saturation of the sorbent they take a horizontal position on the water, and even the presence of screens does not guarantee protection against oil penetration beyond the fencing strip, as well as the fact that the sorbent material It is disposable and is disposed of after spinning.

A known boom design, consisting of separate sections with inflatable cylindrical floats, equipped with a skirt with ballast in the lower part, the end face of the float of each section is placed in the end recess of the float of the adjacent section (RU 39899, 08/20/2004).

The disadvantage of this design is that it only localizes the distribution of petroleum products, and their collection is carried out using special oil collectors, as well as the fact that it takes quite a long time to fill the floats to prepare the boom for operation.

Closest to the proposed utility model is a barrage-sorbing boom of constant buoyancy with a cylindrical float in the surface part, a sorbing element and a curtain with ballast in the form of a pocket with a chain located in the underwater part. The bon is equipped with a sorption compartment installed along the entire length of the float on its front surface and made in the form of a mesh pocket, the upper part of which is fixed to the outer shell of the float, and the lower part is located in the underwater part of the boom and attached to the upper part of the curtain. The sorbent element is placed in the sorption compartment with the possibility of its replacement when saturated with oil (RU 2217548, 02/01/2001).

The disadvantages of this model include the constructive solution of the sorption compartment of fiberglass mesh:

- fastening of the upper part of the compartment to the shell of the boom is carried out using a Velcro fastener, whose service life is incomparably shorter than the service life of the boom and will require repeated replacement;

- fastening the lower part by welding and sewing directly to the curtain; the grid itself is rather thin and fragile material and, accordingly, repair or replacement of the sorption compartment will be a long and laborious process, impossible on site and requiring significant costs.

- the sorbent element is made of a non-woven sorbent web rolled up and not having any shell or devices for removing it from the compartment, which makes this process rather laborious.

The problem to which the proposed utility model is directed is to create a permanent buoyancy boom with sorbing pads that would eliminate the above disadvantages.

The technical result achieved by the implementation of this utility model is to expand the functionality by providing a double function with a boom - both barrage and barrage-sorbing, reducing the cost of operation and maintenance, increasing the efficiency of localization and cleaning of oil pollution on the water surface at the use of a reusable sorbent element in the construction of a boom.

The specified technical result is achieved in the boom barrier of constant buoyancy, consisting of at least one section of PVC fabric forming a float chamber, divided into at least five airtight compartments, each of which contains a float of cylindrical shape made of polyethylene foam, and having a steel rope in the upper part for stiffening, a pocket with a ballast chain in the underwater part, two duralumin strips at the ends of each section for connecting them to each other, handles from webbing slings for extraction sections made of water, and sorbing liners of reusable use for collecting oil products, made with the possibility of fastening to each section using polyethylene clamps with carbines.

The float is made of sheet polyethylene foam, rolled up and welded at the edges.

The handles are secured between the airtight compartments using a bolted connection.

The steel rope is placed in a polyamide braid.

The pocket with a ballast chain is made in the form of a pipe and runs along the entire length of each section.

The ballast pocket has openings for air outlet and water inflow / outflow.

Sorbent pads are placed on one side of each section.

Sorbent pads are a sorbent non-woven fabric, rolled up, placed in a shell of a polymer mesh.

Each section contains metal half rings, which on the one hand are made with the possibility of heat-welding using strips of PVC fabric to the float chamber, and on the other hand, are made with the possibility of connection with polyethylene clamps through carbines.

The essence of the utility model is illustrated by drawings, where figure 1 shows a General view of the boom boom of constant buoyancy; figure 2 is a section aa in figure 1.

The boom boom of constant buoyancy of the BZPP (BZPP) model with sorbing plates 4 of the proposed design consists of at least one section and is made of special bonded PVC fabric that is resistant to oil, wear and frost resistant. In the upper part of the PVC - fabric is welded into a pipe and forms a float chamber, divided into at least five airtight compartments 8, each of which contains a cylindrical float 7 made of polyethylene foam, giving BZPP positive buoyancy. The float 7 is made of sheet polyethylene foam (foamed polyethylene), rolled up and welded at the edges. Sealed compartments 8 are made 2000 mm long, on the border of compartments 8 in the upper part of the section there are handles 6 made from webbing-slings, which are used for transfer of BZPP. Loops 6 are strips of a strong nylon braid-slings attached between the tight compartments 8 to the PVC fabric with a bolt connection. To give the BZPP the necessary rigidity in the upper part of the section, a galvanized steel cable 2 (cable) is laid in a tube-like pocket 10 in a polyamide braid, which prevents abrasion of PVC fabric under working loads. In the lower underwater part of the section, a pocket 9 is made in the form of a pipe 50 mm high with a ballast chain 1, which gives 2/3 of the BZPP negative buoyancy. Holes are punched in pocket 9, framed by grommets, for air outlet and water inflow / outflow for quick precipitation of BZPP and ease of operation.

On the front surface of the BZPP there are fasteners for sorbing plates 4, which are metal half rings (not shown).

The half rings are fixed using a strip of PVC fabric welded by heat welding to the shell of the boom.

Sorbent pads 4 are a sorbent non-woven fabric with a high sorption capacity, rolled up and placed in a shell of a polymer mesh. Outside the lining, at equal distances, polyethylene clamps 5 with metal carabiners mounted on them are located. Thus, the sorbing pads 4 are easily and reliably fastened by carbines to half rings on the sections (shell) of the BZPP. This design allows you to quickly and repeatedly replace sorbent linings 4 saturated with oil products with new ones, and the allowable number of sorption-regeneration cycles for one sorbing element is at least 15 cycles.

BZPP sections are interconnected using a reliable bolted connection of duralumin strips 3 located at the edges of the sections. The design of the bolted connection is universal, allows you to connect any type of BZPP manufactured by our company together, and is an additional advantage of this utility model.

The number of sections is determined by the width of the reservoir and the size of the oil slick.

BZPP are delivered to the place of operation in collapsed form. The installation of a water barrier is carried out by pulling the last section with a vessel or a winch mounted on the opposite bank. The extreme section of the other end of the BZPP is fixed relative to the shore with the help of an anchor.

The manufacturer reserves the right to produce sections not only of standard length (10 m), but also of other lengths at the request of the customer, which is provided by TU 7429-003-99089086-2008 p. 1.

Claims (9)

1. Boom boom of constant buoyancy, characterized in that it consists of at least one section of PVC fabric forming a float chamber, divided into at least five airtight compartments, each of which contains a cylindrical float made of polyethylene foam, and having a steel rope in the upper part for stiffening, a pocket with a ballast chain in the underwater part, two duralumin strips at the ends of each section for connecting them to each other, handles from webbing slings in the upper part for extracting the section and water and sorbing laths reusable for collecting oil, adapted to be attached to each section using plastic clamps with snap hooks. 2. The boom according to claim 1, characterized in that the float is made of sheet polyethylene foam, rolled up and welded at the edges. 3. The boom according to claim 1, characterized in that the handles are secured between the sealed compartments using a bolted connection. 4. The boom according to claim 1, characterized in that the steel rope is placed in a polyamide sheath. 5. The boom according to claim 1, characterized in that the pocket with a ballast chain is made in the form of a pipe and runs along the entire length of each section. 6. Boom barrier according to claim 5, characterized in that the pocket with a ballast chain has openings for air outlet and inflow / outflow of water. 7. The boom according to claim 1, characterized in that the sorbent pads are placed on the side of each section. 8. The boom according to claim 7, characterized in that the sorbent pads are a sorbent non-woven fabric, rolled up, placed in a shell of a polymer mesh. 9. The boom according to claim 1, characterized in that each section contains metal half rings, which on the one hand are made with the possibility of heat welding using strips of PVC fabric to the float chamber, and on the other hand, are made with the possibility of connection with polyethylene collars through carbines.