RU194715U1 - Bottom module for the rehabilitation of contaminated areas of the seabed - Google Patents

Abstract

The utility model “Bottom module for the rehabilitation of contaminated areas of the seabed” relates to devices for the rehabilitation of anthropogenic impact on the marine environment and the formation of bottom marine biocenoses in contaminated areas of the seabed with heavy hydrocarbons in oil and gas exploitation areas. FIG. 1 shows a general view of the utility model “Bottom module for the rehabilitation of contaminated areas of the seabed”, FIG. 2 is a frontal sectional view of the model, and FIG. 3 - mesh box. The bottom module contains a supporting frame (1), a mesh box (2 in Fig. 1; Fig. 3), an artificial substrate (3.4), loads (5) and buoys (6) to maintain the buoyancy of the structure. The supporting frame is a spatial lattice soldered from metal-plastic perforated pipes used for tap drinking water, the size of the lower and upper bases of at least 105x105 cm and a height of 55 cm. Each face of the frame has longitudinal jumpers (also made of pipes) for reinforcing the frame, and the upper face-cover is removable. A mesh box (Fig. 3) with a base size of at least 100x100cm and a height of 50cm is connected from plastic mesh cloths with a mesh of at least 2cm. Connections of paintings made polypropylene tourniquet (7), threaded through the mesh. The box is filled with a substrate consisting of tubes (4) and a net web (3), installed in a supporting frame and closed with a lid, which is also tied with a polypropylene tow. The filling of the box is carried out as follows: first, a substrate of five layers of net fabric (3) is laid, then a layer of tubes (4), alternating, thus, the box is filled to the top with the last layer of net fabric. Buoys (5) are installed on the perimeter of the upper base of the supporting frame on the protruding vertical tubes to ensure the buoyancy of the structure. The module was fixed at the bottom of the reservoir by fixing weights to it (5). The load, which is a 20x20x20cm cube with a built-in eyelet (8) for the cable (9), made of reinforced concrete, is tied to the supporting frame in each corner with a polypropylene cable of at least 30 cm long, which ensures the distance between the module and the bottom surface, maintains flow and does not interferes with natural processes of oil destruction and other pollution of the seabed. The number of modules used depends on the shape and area of the seabed damage. They are positioned so that the entire disturbed area is beneath the bottom modules. The module design is lowered onto the affected area of the seabed, where it begins to grow with hydrobionts-filtrators and is populated by representatives of the bottom biocenosis, provides a favorable hydrological and hydrochemical environment for the organisms of the community forming on it due to transparency structure and its location in the water column, in combination with the maximum active surface area for periphyton and a significant receiving potential in relation to the native species of infauna that settle in the porous material of the substrate from the net, thereby compensating for the damaged area of the seabed, re-creating the feed chain and restoring the biocenosis as a whole. The absence of solid surfaces and the gap between the modules and the bottom surface allows natural natural processes of oil destruction, transformation as a result of oxidation, biodegradation and photochemical processes, allows water flows to pass through the structure, ohms substrates with the organisms inhabiting them, providing the latter with food and removing waste products. The through structure and porous surface of its elements reduces the hydrodynamic load on the structure from wave action and flow by reducing the resistance and flow around the water flow. Thus, the described design of the bottom module ensures achievement of the technical result, which consists in the formation of a destroyed bottom biocenosis again on the substrate of the bottom module, stimulating benthic community in improving the affected area of the seabed by implantation with an artificial substrate of the bottom module, which leads to the restoration of the natural bottom biocenosis, preserving the energy balance of the ecosystem, without concern and unlimited in time, allowing the natural processes of oil destruction, transformation as a result of oxidation, biodegradation and photochemical processes.

Description

      Integrated development of offshore oil and gas fields is associated with a significant risk of environmental damage. To ensure environmental safety, a unified, consistent technical and environmental policy is required by the mining company, as well as the consolidation of efforts of industry and state enterprises. [1].

    When oil is released into the environment, it contacts the atmosphere or the soil and natural waters of rivers and seas. Oil spilled on the surface of water bodies, after a year appears at the bottom of the reservoir due to sorption on solid particles, as well as due to an increase in density [2].

     A number of physical, physicochemical, and biological processes and transformations occur with the components of oil. In the aquatic environment, oil and oil products are fractionated, as a result of which they can exist in several aggregate states:

molecular film;

film up to several mm thick (slick);

emulsion "water in oil" or "oil in water";

bottom sediments.

     The hydrocarbon composition of bottom sediments reflects the processes of sorption and biotransformation during sedimentation. Sedimentation is a process related to the fact that insoluble oil residues in their specific gravity approach or exceed the density of water and in this case they sink [3].

     With regard to environmental measures aimed at protecting water bodies or their parts and environmental rehabilitation, the Rules for the Budget Designing of the Federal Water Resources Agency for 2017 and for the planning period 2018 and 2019 indicate the following: “Work projects in this direction may include such types works as clearing the water body from bottom sediments, extracting objects of mechanical clogging of water bodies, including large-sized (with the exception of elements of hydraulic structures (GTS) and flooded vessels), aeration of water bodies, algolization, other types of biological remediation of water bodies, creation of a bioplate, biogenic fastening of coastal slopes and coastal strip within coastal protective strips, including tinned and fixed shrubbery, including the use of geogrids and geotextile materials, the elimination of accumulated pollution within the coastal protective strips [4].

     The implementation of measures for the restoration of water bodies is provided only in the event of an oil and oil product spill. According to paragraph 8 of the Rules for the organization of measures for the prevention and liquidation of oil and oil products spills on the territory of the Russian Federation (approved by the Decree of the Government of the Russian Federation of April 15, 2002 N 240), measures must be taken to eliminate the consequences of oil spills, while these works can be considered completed upon reaching an acceptable level of residual content of oil and oil products (or their transformation products) in soils and soils, bottom sediments of water bodies [5].

     Reclamation is a practical and costly undertaking, and if the issue is clear for onshore remediation, then for surface water bodies (including the bottom of surface water bodies, regardless of their depth), the relevant legislation and methods have not yet been developed.

     Obviously, the stable functioning of the natural ecosystem is possible only if the conditions for the reproduction of biological resources are preserved. This condition can be fulfilled by constructing artificial systems that ensure the maximum speed of rehabilitation of the disturbed area. The ecological balance of the ecosystem is determined by the ratio of its incoming and outgoing parts and is based on the principles of conservation of matter and energy. The volume of compensation measures is determined through the production characteristics of trophodynamic links, which should be created in order for the integral balance of the ecosystem to become equal to its initial balance. The methodological essence of this technique is the need to find measures to regulate the functional stability of natural ecosystems using artificial measures or devices. This technique is widely used in the practice of restorative nature management, in the practice of marine use this technique has not yet found its application. Therefore, the basis of compensatory measures is to take the restoration of the primary productivity of bottom landscapes, the creation of conditions for the resumption of animal habitat and bringing the energy balance to a state close to the original [6].

    Of all the known methods and methods for eliminating pollution by oil products in the water sphere, four main methods should be distinguished: mechanical, carried out using all possible designs and devices for collecting oil; physical and chemical, based on the use of physical and chemical phenomena; biological - with the help of microbiological cultures and hydrobionts-filtering devices and a chemical photo, passing under the influence of sunlight and catalysts [7].

     Not all control methods, including those widely used at present, satisfy the requirements of nature conservation. Thus, the widespread use of detergents in the response to oil spills often causes additional, and sometimes even greater harm to marine life. Therefore, to protect the biological resources of the sea under anthropogenic pressure, new safe methods for cleaning the marine environment are needed.

     There is a method for biological purification of oil and oil products, including the use of oil-oxidizing bacteria (Pseudomonas) [8].

     The disadvantage of this method is that the process of purification of the marine environment is weak, oil products remain in the water for a long time and spread very quickly over the water area.

      A known method of purification of the marine environment from oil, oil products and other pollutants by filtering aquatic organisms, namely the Black Sea mussel. Mussels are placed in oil spills. By filtering seawater, mussels release it from emulsified oil [9].

     The disadvantage of this method is its low efficiency, because marine invertebrates are scattered randomly. Oil products are not localized and therefore spread very quickly across the water area, in addition to this, only some fractions of oil are caught by mussels, and this makes it difficult to clean the marine environment.

     Known invention No. 2,570,460 Published: 12/10/2015 Bull. No. 34 A method for cleaning bottom sediments of water bodies from oil and oil products and a device for its implementation. [10] The invention relates to the field of environmental protection and is intended for the purification of natural and artificial reservoirs, the bottom of which is contaminated with oil and oil products. A method for cleaning bottom water bodies from oil and oil products includes separating oil and oil products from bottom sediments, raising the oil-containing mixture to the surface of the reservoir and collecting oil and oil products with their subsequent disposal.

     The disadvantage of this method is that it does not contain compensation measures that should be created so that the integral balance of the ecosystem becomes equal to its balance before the start of technological intervention.

    The well-known "Method of biological treatment of the marine environment", invention No. 2 186 035, published: 2002.07.27 [11]. A method of biological purification of the marine environment, including the placement of marine invertebrates in places of water pollution with oil, oil products, organic and mineral substances, characterized in that marine macrophytes are additionally placed in places of water pollution, and they are placed around the source of pollution in plants for the cultivation of marine aquatic organisms in the surface and / or the bottom layer of water, and / or throughout the thickness, in a checkerboard pattern, in 6 or more rows, while slowly growing and adult are placed on the inner rows ie individuals growing macrophytes and marine invertebrates, and on the middle and outer rows - juveniles of marine aquatic organisms.

          A known method of restoring benthic communities of the Barents Sea coastal zone after dredging. Invention No. 2511300, published on 04/10/2014. Bulletin No. 10, we have chosen as a prototype [12].

     The invention relates to methods for the formation of bottom marine biocenoses after dredging. The method involves the study of habitat conditions, abundance, species diversity, boundaries of the distribution of benthos at the site of dredging, the determination of means of compensation for alleged damage and the optimal period of work. After dredging in areas where the living conditions are optimal for the development of mussels and other restored benthos species, with a depth of 5-10 m, with good water exchange and the presence of cans of natural mussel populations at the closest distance, artificial biotopes are established.

     The disadvantages of these methods is that the localization of marine hydrobionts and marine macrophytes in the area of anthropogenic impact is a laborious and costly method, the restoration of oil-contaminated soils stretches for a long time, not ensuring the elimination of the damage already done. As a result, complete restoration of disturbed soil remains to the share of natural factors; the process becomes long and unreliable.

      The technical task of the proposed utility model is to create a bottom module as an artificial ecosystem that provides the maximum rate of rehabilitation of the disturbed area, which compensates for the contaminated area of the seabed, create conditions for the rehabilitation of the primary productivity of the sea bottom biocenosis and the resumption of animal habitat, and bring the energy balance of the ecosystem to its original state.

     The technical result is expressed in compensation (complete replacement) by the bottom module of the contaminated areas of the seabed, where the newly destroyed bottom biocenosis is formed, the restoration of the benthic community is stimulated, the affected part of the bottom of the seabed is healed by implantation with an artificial substrate of the bottom module, which leads to the restoration of the natural bottom biocenosis, while maintaining the energy ecosystem balance, carelessly and unlimited in time giving the opportunity to be carried out naturally native oil degradation processes, transformation by oxidation, biodegradation and photochemical processes.

     The solution of the technical problem is carried out using the utility model “Bottom module for the rehabilitation of contaminated areas of the seabed”.

     The proposed utility model relates to devices for the rehabilitation of anthropogenic impact on the marine environment and the formation of bottom marine biocenoses in contaminated areas of the seabed with heavy hydrocarbons in oil and gas exploration areas.

     In FIG. 1 shows a general view of the utility model “Bottom module for the rehabilitation of contaminated areas of the seabed”, FIG. 2 is a frontal sectional view of the model, and FIG. 3 - mesh box. The bottom module contains a supporting frame (1), a mesh box (2 in Fig. 1), an artificial substrate (3,4), loads (5) and buoys (6) to maintain the buoyancy of the structure. The supporting frame is a spatial lattice soldered from metal-plastic perforated pipes used for tap drinking water, the size of the lower and upper bases of at least 105x105 cm and a height of 55 cm. Each face of the frame has longitudinal jumpers (also made of pipes) for reinforcing the frame, and the upper face-cover is removable. A mesh box (Fig. 3) with a base size of at least 100x100cm and a height of 50cm is connected from cloths of plastic mesh with a mesh of at least 2cm. Connections of paintings made polypropylene tourniquet (7), threaded through the mesh. The box is filled with a substrate consisting of two components: scraps of metal-plastic perforated pipes (4) for drinking water of different diameters, but not less than 2 cm and different lengths, but not more than 100 cm, and a net cloth (3) made from nylon mesh with mesh from 1 to 3 cm, installed into the supporting frame and is closed by a lid, which is also tied with a polypropylene cord. The box is filled as follows: first, a substrate of five layers of net fabric (3) is laid, then a layer of tubes (4), alternating, thus, the box is filled to the top with the last layer of net fabric. Buoys (5) are installed along the perimeter of the upper base of the supporting frame on the protruding vertical tubes to ensure the buoyancy of the structure. The module was fixed at the bottom of the reservoir by fixing weights to it (5). The load, which is a 20x20x20cm cube with a built-in eyelet (8) for the cable (9), made of reinforced concrete, is tied to the supporting frame in each corner with a polypropylene cable no more than 30 cm long, which ensures the distance between the module and the bottom surface, maintains flow and does not interferes with natural processes of oil destruction and other pollution of the seabed.

      The number of modules used depends on the shape and area of the seabed. They are positioned so that the entire disturbed area is under the bottom modules.

      The module design descends to the affected area of the seabed, where it begins to grow with hydrobionts-filtering and is inhabited by representatives of the bottom biocenosis, provides a favorable hydrological and hydrochemical regime of the living environment of the organisms of the community formed on it due to the transparency and permeability of the structure and its location in the water column, in combination with the maximum active surface area for periphyton and a significant receiving potential in relation to the native species of infauna settling in pores stomas substrate material of perforated tubes and the netting, thereby compensating for the damaged area of the seabed, re-creating the feed chain and restoring biocoenosis as a whole.

     The absence of continuous surfaces and the gap between the modules and the bottom surface makes it possible to carry out natural processes of oil destruction, transformation as a result of oxidation, biodegradation and photochemical processes, allows water flows to pass through the structure, washing the substrates with the organisms inhabiting them, providing them with food and removing products life activity.

      The through structure and the porous surface of its elements reduces the hydrodynamic load on the structure from wave action and current by reducing drag and flow around the water.

      Thus, the described design of the bottom module ensures the achievement of a technical result, which consists in the formation of a destroyed bottom biocenosis on the substrate of the bottom module, stimulation of the restoration of the benthic community in the healing of the affected area of the seabed by implantation of an artificial substrate of the bottom module, which leads to the restoration of the natural bottom biocenosis, while maintaining the energy balance ecosystems, carelessly and unlimited in time giving the opportunity to implement They are involved in natural processes of oil destruction, transformation as a result of oxidation, biodegradation, and photochemical processes.

     The experimental version of the proposed utility model “Bottom module for the rehabilitation of contaminated areas of the seabed” was carried out at LLC “Research Institute of the Caspian Sea Problems” and located in the northern part of the Caspian Sea in the area of the development of the field named after V. Filanovsky.

Literature.

1. Ensuring environmental safety in the development of offshore oil and gas fields. I.A. Zaikin, Head of the Department of Industrial Safety, Ecology and Scientific and Technical Works, OAO LUKOIL, 2011.

2. Oil spill response. Land reclamation after oil pollution.

https://www.pkvertikal.com/news/2014/ustranenie_razlivov_nefti_rekultivaciya_zemel_posl.htm.

3. Biochemical behavior of oil in the aquatic environment.

https://uchebnikfree.com/ekologiya/biohimicheskoe-povedenie-nefti-vodnoy-54453.html

4. Decree of the Government of the Russian Federation of February 5, 2016 N 79 "On approval of the Rules for the protection of surface water bodies". Water Code of the Russian Federation. Order of the Federal Water Resources Agency dated June 23, 2016 N 123 On approval of regulations and organizational measures for the formation of budgetary designs for the Federal Water Resources Agency for 2017 and for the planning period 2018 and 2019.

5. RD 52.24.609-2013 Guiding document. Organization and conduct of monitoring of the content of pollutants in the bottom sediments of water bodies. Date of introduction 2013-09-02.

6. Preobrazhensky BV, Marine lands and how we dispose of them. http://arktikfish.com/index.php/morskaya-i-okeanicheskaya-akvakultura/384-morskie-ugodya-i-kak-my-imi-rasporyazhaemsya.

7. Methods for removing oil pollution. Methods of eliminating oil pollution from the water surface and soil.

https://helpiks.org/8-14312.html

8. Mironov O. G., On the issue of self-purification of sea water from oil products. - Hydrological journal, 1969, 4, p. 89-93.

9. Mironov O. G., Biological resources of the sea and oil pollution. - M., 1972, p. 79-81

10. Invention No. 2,570,460 Published: December 10, 2015 Bull. Number 34.

11. Invention No. 2186035, published: 2002.07.27

https://vuzlit.ru/475145/sposob_biologicheskoy_ochistki_morskoy_sredy.

Invention No. 2511300, published on 04/10/2014. Bulletin No. 10.

Claims (8)

1. The bottom module for the rehabilitation of contaminated areas of the seabed, consisting of a supporting frame, mesh box, substrate, buoys and cargo, characterized in that the supporting frame is a spatial lattice soldered from metal-plastic perforated pipes used for tap drinking water, and mesh a box filled with artificial substrate is installed in the supporting frame and is closed by the upper face of the supporting frame, while along the perimeter of the upper base of the supporting frame on protruding vertical pipes bkah installed buoys and fixing the module on the bottom of the reservoir is formed loads tied at the corners of the bottom face of the carrier frame polypropylene rope length not exceeding 30 cm. 2. The bottom module according to claim 1, characterized in that the supporting frame is at least 105 x 105 cm in height and 55 cm in height on the lower and upper base. 3. The bottom module according to claim 1, characterized in that the mesh box with a size of at least 100x100 cm and a height of 50 cm along the lower and upper bases is connected from plastic net webs with a mesh of at least 2 cm. 4. The bottom module according to claim 1, characterized in that the upper face-lid of the supporting frame is removable. 5. The bottom module according to claim 1, characterized in that the connections of the mesh box webs are made of polypropylene tow, threaded through the mesh. 6. The bottom module according to claim 1, characterized in that the substrate consists of two components: scraps of metal-plastic perforated pipes for drinking water of different diameters, but not less than 2 cm and different lengths, but not more than 100 cm, and a mesh cloth made of nylon mesh with a mesh of 1 up to 3cm. 7. The bottom module according to claim 1, characterized in that the box is filled with a substrate as follows: first, a substrate of five layers of net fabric is laid, then a layer of tubes, alternating, thus, the box is filled to the top with the last layer of net fabric. 8. The bottom module according to claim 1, characterized in that the cargo is a cube 20x20x20cm with a built-in eyelet for the cable, made of reinforced concrete.

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