LT4583B - Method of cleaning the soil of port hydraulic engineering from petroleum products - Google Patents

Abstract

FIELD: environment control technology. SUBSTANCE: method is intended for removing petroleum products penetrated into earth mass at ports due to leakage from pipelines or local spilling at loading of vessels. Removing of petroleum products from areas adjacent to hydraulic engineering structures at ports having sheet-piling wall is effected by collecting them and branching away by means of vertical bore-holes which are provided with pumps. Vertical bore-holes are arranged in zone close to port structures. Pitch of bore-holes in row is equal to 17-26 diameters of vertical bore-holes. Delivered into this zone is live steam through horizontal or inclined drain-steam needles which are installed below level of water-bearing layer and they are inserted into openings in sheet-piling wall of hydraulic engineering structure with application of chamber hermetically connected with sheet-piling wall. Utilization of aforesaid method and arrangement improves efficiency of cleaning earth at port hydraulic engineering structures from petroleum products and prevents fouling of port water area with petroleum products. EFFECT: higher efficiency. 9 cl, 2 dwg

Description

The present invention relates to the achievement of an adequate level of environmental protection in the port waters, namely to clean the soil of the port's hydrotechnical structures from petroleum products falling into the soil mass during their operation, through oil pipelines or in the case of oil loading on ships.

There is a known method of cleaning oil or oil-contaminated soil by rinsing with water and subsequently collecting, which freezes the ice and soil wall along the contaminant contaminant of the aquifer along its contamination contaminant along the contaminant contour, washing the oil or petroleum products. pumping water into the aquifer through a pressurized well until the level of oil or petroleum-containing water rises to the surface of the day (RU, Patent No. 2071671, cl. B 09 C 1/00, E 02 B 15/04, Ei 02 D 31/00, published 97.01.10).

The disadvantage of this method is that by washing the oil or petroleum products by pumping the water into the bed aquifer via a pressure well, raising the level of contaminated water to the surface of the day, proper cleaning of the soil mass from these pollutants is not achieved. easily leachable fractions of oil pollutants in water. The asphalt and resin fractions migrating inert and well retained in the soil remain in the soil massif. This method of cleaning can be used only for the initial reduction of abundant soil mass contamination.

In addition, freezing the ice and soil wall in the soil massif along its contaminant contamination before leaching the oil or petroleum products is associated with a decrease in the temperature of the ice and soil wall soil massif, which adversely affects its oil and petroleum product removal efficiency. temperature increases the viscosity of said oil contaminants. As a result, the speed of their transition to the water phase is noticeably reduced. At the same time, the migratory inert fractions of asphalt and resin become more immobile and the soil retains even more strongly.

A more preferred method is to collect and remove oil and petroleum products from groundwater surface vertical wells with pumps in them, where wells are located in the central part of the oil contaminated area along closed outer and inner contours, by the way, outer contour wells are located deeper than inner contour wells. and petroleum products are collected by means of internal contour drilling from the depression depression center formed (SU, Approval No.1772315, Cl. E 02 B 11/00, published 9.10.30).

The disadvantage of this method is that it does not achieve a sufficient level of petroleum product decontamination, since only water-soluble and free petroleum products can be collected by vertical wells with pumped pumps, while the migrating inert fractions of the asphalt resin are retained in the soil mass.

SUMMARY OF THE INVENTION The object of the present invention is to find a way to clean the oil-intact soil of the port's hydrotechnical structures without stopping its operation, so that not only the water-easily and easily removable oil and petroleum product fractions can be collected and removed, but also migratively inert fractions of petroleum products, rendering them fluid and easily removable, which makes it possible to increase the efficiency of depollution of the soil of the port's hydrotechnical structures and to protect the port waters from oil contamination.

This technical result is achieved by our proposed method: when cleaning the soil of hydroelectric barrels with petroleum products using vertical boreholes with pumps installed in them, the vertical boreholes shall be located at least in the prefrontal area of the hydrotechnical bay with a step size of 17-26 vertical boreholes , then fresh steam is injected into the area by means of horizontally or inclined drainage steam needles, which are inserted below the aquifer level through openings in the wall of the hollow hydrotechnical structure using a hermetically connected chamber.

Vertical wells can be arranged in chess order in the pre-cordon zone of the hydrotechnical structure.

Vertical boreholes in the array area may be equipped with vertical perforated needles for additional fresh steam delivery.

Steam drain needles, horizontally or inclined, allow chemical detergents to be inserted alternately with fresh steam.

Vertically reshaped steam needles allow chemical detergents to be used alternately with fresh steam.

Compressed air can be fed through fresh steam through horizontal or inclined drainage steam needles.

Fresh steam may be supplied alternately to compressed air through drainage needles horizontally or inclinedly.

After the fresh steam, pressurized air can be fed through the vertically perforated steam needles.

Fresh steam can be supplied alternately with compressed air through perforated steam needles positioned vertically.

Removal of petroleum products from vertical boreholes by means of pumps allows additional collection of petroleum products from vertical boreholes by water sorption.

Arrangement of vertical wells fitted with pumps therein for collecting and removing petroleum products, at least in a pre-cordon hydrotechnical zone with a step size of 17 to 26 vertical wells, simultaneously supplying fresh steam to that area by means of horizontally or inclined drainage steam needles installed below the aquifer level through a hole in the wall of the hydroelectric structure, using a chamber hermetically connected to it, enables the cleaning of oil-intact harbor hydroelectric barrels without stopping its operation, so that not only water-soluble and easily fractions of petroleum and petroleum products are eliminated, but also fractions of petroleum products which are inert to migration and which are highly retained in soil, making them fluid and easy to remove from the soil. to. This makes it possible to increase the efficiency of the oil removal of the soil of the hydrotechnical structures of the port and to protect the port waters from oil pollution.

By supplying fresh steam through horizontally or inclined drainage steam needles, which are placed below the aquifer level, the soil mass is heated and the oil contained therein is liquefied, which enables all fractions of petroleum products to be actively fluid and easily removed from the soil. the horizontal or inclined drainage steam needles, located below the aquifer, allow fresh steam to be introduced into the soil column below the maximum oil level front (level) by fully liquefying petroleum products in the soil massif.

The order of vertical boreholes, consisting of 17-26 vertical boreholes, shall be determined by the effective liquid oil vapor collection area (spindle) for each vertical borehole, taking into account the location of the port's hydrotechnic structural force elements and the overall surface resistance. building reliability.

However, the positioning of vertical wells in increments of less than 17 vertical wells results in a non-technologically motivated excessive approach of adjacent vertical wells, which may affect the resistance of the topcoat of the hydrofoil structure and deform it in the sense of integrity, the fact that the hydrofoil structure is under heavy stress during operation may reduce the overall reliability of the whole hydrotechnical structure. In addition, by placing vertical boreholes in such a step, the force elements of the port's hydrotechnical structure can be damaged during drilling.

When the vertical wells are laid in increments of more than 26 vertical wells, there will be areas of the bulk soil that are not covered by the fresh oil vapor collection areas. This reduces the efficiency of oil product collection and disposal, and thus the efficiency of soil removal from oil products. In addition, the placement of vertical wells in such a step may also damage the force components of the port's hydraulic structure during drilling.

The placement of vertical wells equipped with pumps for collecting and removing petroleum products in the foreshore of the hydrotechnical structure and the supply of fresh steam to that area enable the removal of the soil from the petroleum prehydrated structure, thereby providing a barrier to the petroleum product part of the hydrotechnical structure into the port waters and protect it from oil contamination.

The chess arrangement of vertical wells in the foreshore of the hydroelectric structure increases the efficiency of oil product collection in the water phase resulting from the heating of the oil-contaminated soil mass with fresh steam, as this results in a more compact oil product collection area.

In addition, fresh steam is intensified by the heating of the oil-contaminated soil and the liquefaction of the petroleum products contained therein through the addition of a steam needle pierced through a vertically embedded soil array. Delivering fresh steam with vertically-ground perforated steam needles, combined with fresh steam and horizontal or inclined drainage steam needles below the maximum concentration on the oil product front, significantly shortens the time required to warm the oil-contaminated soil and liquefy all petroleum products, whereas horizontally or inclined drainage steam needles form upward steam flows that invert the bottom of oil-contaminated soil from bottom to top, while vertically-mounted perforated steam needles radiate a horizontal stream of fresh steam into the bed of the oil-contaminated soil, intersecting streams covering the entire volume of the cleaning soil array.

The use of either horizontal or inclined drainage steam needles or perforated steam needles inserted vertically into the soil, alternating with fresh steam, can intensify the process of cleaning the soil mass from oil products, for example by cleaning heavily oil-soiled soil massifs.

By supplying compressed air after fresh steam or by supplying fresh steam alternately with compressed air, it is possible to increase the volume of heated fresh steam soil mass and thereby liquefy much more oil in the soil mass.

Removal of petroleum products from vertical wells by pumps removes petroleum products from the water surface of the vertical wells by sorption, thereby removing the petroleum products. In this way, the required (permissible) residues of the petroleum products in the treated soil mass can be achieved.

BRIEF DESCRIPTION OF THE DRAWINGS The following drawings illustrate the invention. Fig. 1 shows the technological scheme of the port's hydrotechnical building soil cleaning from oil products, a general view. Figure 2 shows this in section.

Purification of oil products from the port hydrotechnical structure shall be carried out as follows.

Contaminated as a result of oil spills from pipelines or spillages of oil products during loading of ships and having to be cleaned, the port's hydrotechnical structure ground shall be divided into separate sections. The length of each section is determined by the size of the airtight chamber 2, which is hermetically connected to the barrier wall. For example, if the length of the airtight chamber 2 is 13.02 m, the length of the section will be 8-12 m. The width of each section depends on the constructional features of the hydro-structural part of the apex. As an airtight chamber 2, a device for the repair of underwater hydrotechnical structures can be used (RU, patent no. 2098546, cl. E 02 B 1/00, published December 12, 1997, No. 34), comprising a sectional prefabricated frame work chamber with support work platform and with brackets in the form of brackets. The working chamber is equipped with a flushing device. the device is fixed to the hydrotechnical structure by means of a frame-template, and the frame-template is fastened with bolts to the hollow wall and struts to the upper part of the hydraulic structure. The prefabricated sectional frame, in addition to the working chamber, has two hermetically sealed spaces that are filled with water to better fit the unit to the frame-template.

Vertical boreholes 3 are made in each section for cleaning, and perforated protective pipes with mesh filters 4 are installed. The amount of vertical boreholes 3 in each section depends on the diameter of the boreholes, their pitch in the queue, the number of rows and the length of the section. For example, if the boreholes have a diameter of 159 mm, they will have a step length of 3360 mm and a section length of 11 m, the chess bore holes will require seven boreholes. Vertical boreholes 3 are equipped with centrifugal pumps 5 for a single pump for 3-4 boreholes. Centrifugal pumps 5 are connected to the drain manifold by means of pressure hoses 6. Centrifugal pump suction valves 7 are installed in bores 3 at a level of 1.5 to 2.0 m.

The drainage steam needles 8, through which fresh steam is fed, are mounted in the soil array below the aquifer by means of an airtight chamber 2. After attaching the airtight chamber 2, 1 of the airtight chamber 2 is drilled by a drilling machine 83 in the hydrotechnical structure. the holes, then through which the drainage steam needles are inserted into the soil array 8. The holes in the {conductive walls 1) are fitted with seals at the locations of the drainage steam needles. {The soil array is drained by hand or by pneumatic perforator. Steam needle length 1.5 m, diameter 4850 mm. 3-4 such needles shall be installed in each area of the hydrotechnical structure. They are embedded in a soil array 1-1.5 m below the aquifer level.

After cleaning one section of the hydraulic structure, the airtight chamber is separated from the hollow wall of the hydraulic structure and transferred to a new cleaning section.

Oil contaminated soil is cleaned by refining petroleum products in the aqueous phase, which is achieved by heating the oil contaminated soil with fresh steam. The aqueous phase is removed by suctioning it through a centrifugal pump through vertical wells in the soil array. Contaminated water is sucked into the drain manifold, then into the storage tank and then pumped through the flow meter to the storm sewer system.

The oil contaminated soil is heated and the petroleum products are liquefied by feeding fresh steam at a temperature of 130-140 ° C and a pressure of 1-2 atmospheres into the soil layer through drainage steam needles 8.

In order to intensify the heating of fresh oil-contaminated soil and fresh liquefied petroleum products, fresh steam is additionally fed into the vertical well through the perforated steam needles. The combination of fresh steam and horizontal drainage needles 8 can significantly reduce the time required to clean and liquefy petroleum-containing soil contaminated soil.

To increase the volume of heated heated steam massif and to liquefy a larger amount of petroleum products contained therein by supplying fresh steam through drainage steam needles 8 or steam needles 9, they are supplied with compressed air of 2-3 atmospheres or fresh steam is fed through drainage steam needles 8 or steam needles 9 alternately with compressed air.

To intensify the cleaning process, for example by cleaning very heavily contaminated soils, oil soils are cleaned using chemical detergents made of polyacrylamides, which are passed through drain steam needles 8 alternately with fresh steam. Chemical ones can also be used

II detergents through vertically inserted perforated steam needles. Such a chemical detergent may be * such as UBNPP (Universal Oil-Free Oil Detergent).

Removal of petroleum products from vertical wells by centrifugal pumps allows additional collection of film petroleum products from vertical wells by water sorption. In this way, the required (permissible) residues of the petroleum products in the treated soil mass can be achieved.

The film petroleum products are removed from the water surface of the vertical wells by flat mats made of sorbent material, which are subsequently lifted and squeezed into a capacitive reservoir.

The film petroleum products from the water surface of vertical wells can also be collected by probes injected into vertical perforated protective well pipes. Due to fluctuations in the water level in the harbor waters, as the water level in the space behind the slab wall changes, the oil-contaminated water layer moves around the vertical axis of the protective perforated tube, and the oil is absorbed inside the preparation. For this, Biosorbent-A, which contains a microorganism-impregnated absorbent and is considered an effective cleaning agent for petroleum products, may be used. An effective and harmless absorbent of natural minerals are aluminosilicates, such as frothed vermiculite. Micro-organisms living in the sea and naturally purifying water from minor contamination are used as bioproducts. During cleaning, the bio-probe emerges from the well. The oil-saturated preparation is removed and disposed of, and the probe body is filled with a new portion of Biosorbent-A and lowered back into the borehole Purge until the required oil concentration is reached.

Claims (10)

DEFINITION OF INVENTION 1. A method for cleaning the soil of oil-containing hydrotechnical structures having a slab wall using vertical boreholes with pumps, characterized in that the vertical boreholes are located at least in a forward row of the hydrotechnical structure with a step size of 17-26 vertical boreholes, then injects fresh steam into the area through horizontally or inclined drainage steam needles, which are located below the aquifer level through holes in the watertight wall of the hydrotechnical structure, using a chamber hermetically connected thereto. 2. A method according to claim 1, characterized in that the vertical boreholes are arranged in a chess order in the pre-cordon hydrotechnical zone. 3. A method according to claim 1, characterized in that a perforated steam needle is provided in the soil array in the area of the vertical borehole to supply fresh steam. 4. A method as claimed in claim 1, characterized in that the drainage steam needles are horizontally or inclinedly drained by a chemical detergent and alternately supplied with fresh steam. 5. A method according to claim 3, characterized in that the perforated steam needle is inserted vertically through the dry detergent and alternately supplies fresh steam. 6. A method according to claim 1, characterized in that after fresh steam, compressed air is supplied through drainage needles horizontally or inclinedly. 7. A method according to claim 1, characterized in that the fresh steam is supplied alternatively to the compressed air through the drainage steam needles arranged horizontally or inclinedly. 8. A method according to claim 3, characterized in that after fresh steam, pressurized air is supplied through vertically arranged perforated steam needles. 9. The method of claim 3, wherein the fresh steam is supplied alternately to the compressed air through perforated steam needles positioned vertically. 10. A process according to claim 1, characterized in that, after removal of petroleum products from the vertical boreholes, the petroleum products are further collected from the vertical boreholes by sorption.