RU2268593C2 - Method for sulfate reducing bacterium growth suppression - Google Patents

Abstract

FIELD: oil industry.

SUBSTANCE: claimed method includes formation water treatment containing sulfate reducing bacteria with bactericide inhibitor and exposure with magnetic field having strength of 450-655 kA/m for 1.2-1.8 s. Method of present invention in useful in sulfate reducing bacterium growth suppression in produced water and in systems for formation pressure maintaining in oil flow, preparation and hauling.

EFFECT: more effective method for sulfate reducing bacterium growth suppression in formation water.

1 dwg, 2 tbl

Description

The invention relates to the oil industry and can be used to inhibit the growth of sulfate-reducing bacteria (SBA) in field water in reservoir pressure maintenance (RPM) systems, oil production, preparation and transportation.

If there are significant quantities of sulfate salts in the well’s production, the thionic bacteria — SVBs — accelerate the development of sulfate ion (SO ₄ ^{- -} ) to sulfide ion (S ^{- -} ) in the form of hydrogen sulfide (H ₂ S) or sulfide salts.

The development of sulfate-reducing bacteria in the formation water of oil fields leads to undesirable consequences: the resulting hydrogen sulfide and SVB colonies on the walls of the equipment cause corrosion of metal surfaces, the sulfur content in oil increases, and the precipitated iron sulfide leads to clogging of the pores of oil reservoir rocks (reducing the permeability of the formation) and stabilization of the oil-in-water emulsion. So, with an increase in SVB concentration from 100 to 10 ⁵ colonies / ml, the corrosion rate increases from 0.13 to 1.4 mm / year, i.e. almost 10 times with a proportional decrease in the period of trouble-free operation of pipelines and equipment (Saders PFMonitoring & control of sessile Microbes: cost effective Ways to reduce Microbial corrosion - Bombay, India, 1988). As a result, the production and quality of oil is reduced, additional costs are required for the replacement and repair of equipment and more stringent conditions for the destruction of emulsions and the restoration of permeability of formations. In addition, iron sulfide is pyrophoric (it is capable of spontaneous combustion upon contact with air), and hydrogen sulfide formed during the life of the SRB degrades the quality of the oil, making it difficult to process it by poisoning the catalysts and precipitating.

A known method of suppressing the growth of SVB, including cathodic protection of metals and chemical treatment of liquid (Gerasimenko A.A. Influence of cathodic protection of metals on microbial corrosion. Electrochemical. Protection of equipment and structures from corrosion: Mat. Seminar. M .: Publishing House TsRDZ. - 2001, p. 34-35).

The disadvantage of this method is the low efficiency of the cathodic protection of metals from biocorrosion and the high cost of inhibitory treatment of the liquid.

Known means to suppress the growth of SVB, containing a 70% aqueous solution of 1-hydroxy-2- [1,3-oxazetidine] -3-yl-ethane of the General formula C ₄ H ₉ O ₂ N (patent RU No. 2173735, class. 7 IPC С 23 F 11/12, 2001), this ensures both the destruction of bacteria and the protection of metal from corrosion due to the formation of a protective film on the equipment surface.

Its disadvantages are the high cost of the chemical reagent and its irretrievable losses with the PPD water injected into the reservoir.

There is also a method of reducing the growth of sulfate-reducing bacteria in produced water, including the treatment of produced water with bactericides (Smolyanets E.F. et al. Choice of reagents for combating microbiological contamination of objects of JSC "Yuganskneftegaz". Protection against corrosion and environmental protection. Scientific and technical. information collection. - M., VNIOENG - No. 3. - 1997, - p. 8-9).

The disadvantage of this method is a large concentration of bactericide (500-1000 mg / l) and, accordingly, high costs.

The present invention is aimed at solving the problem of reducing costs while maintaining the effectiveness of suppressing the growth of SSC.

The technical result of the invention is to increase the efficiency of suppressing the growth of sulfate-reducing bacteria in formation waters infected with bacterial microflora.

The specified technical result is achieved by the fact that in the method of suppressing sulfate-reducing bacteria in oil preparation systems and reservoir pressure maintenance, including the use of a bactericide by introducing it into the reservoir water from the water supply system, produced together with the oil and then injected back into the reservoir to maintain reservoir pressure, in reservoirs wastewater treatment plants or low pressure water ducts according to the invention, the produced water with an SVB and a bactericide is further treated with a magnetic field of 450-655 k / M for 1.2-1.6 seconds, and the dose of bactericide in the treated produced water is reduced in comparison with the bactericide without magnetic treatment two times or more.

The essence of this proposal is that the combined use of a bactericide and heavy-duty magnetic fields under the proposed dosage and magnetic treatment conditions ensure the death of up to 97-100% of SVB cells with a significant reduction in the dose of the bactericide. Additional magnetic treatment activates the polar molecules of the bactericide, which accelerates the destruction of the biofilm, allows you to destroy the remaining bacteria, increases the adhesion of the bactericide film on the inner surface of pipelines and equipment.

The mechanism of the effect of magnetic treatment on the suppression of SVB is associated with a change in the structure and chemical activity of molecules that change cellular metabolic processes. Bactericidal molecules have their own magnetic moment; when interacting with an external magnetic field, the magnetic moment of the molecule is enhanced and its chemical activity increases.

As shown by laboratory experiments, the results of which are shown in Table 2, a positive result in the destruction of SVB cells can be achieved only with a high magnetic field strength (from 450 to 655 kA / m) and the treatment time of produced (produced) water from 1.2 to 1 , 6 p. With shorter processing times and magnetic fields, the processing effect drops sharply. The increase in magnetic field strength and processing time is associated with the complexity of the implementation of the design of the magnetic activator, and this significantly increases the cost of the magnetic activator.

Such parameters can be ensured only with the use of heavy-duty magnets made of a neodymium-iron-boron or samarium-cobalt alloy and a magnetoactivator design that provides the required processing performance.

The bactericides used are concentrated aqueous solutions of the active toxicant (formaldehyde, glutaraldehyde, mixtures thereof, quaternary salts of ammonium bases, etc.) with the addition of surface-active substances (surfactants), stabilizers. The basis of the majority of bactericides are substances that are similar in structure - aldehydes and their mixtures, therefore the effect of magnetic treatment is the same for different brands of bactericides of different domestic and foreign manufacturers.

As a bactericide, it is advisable to use corrosion inhibitors, which reduce the growth of SVB and form a film on the surface of the metal, for example, the LPE-11B bactericides produced by OAO NPO Tekhnolog (Sterlitamak), Servo UCA-497 manufactured by Servo Delden Ltd (Netherlands ), SNPCH-1004, "Pressure 1007" produced by OJSC "Pressure" (Kazan), etc.

An additional effect of magnetic treatment in this case is a decrease in the overall corrosion rate.

Typical chemical dosage units (BRX, BDR) with the ability to control the dose of bactericide from 0 to 1000 mg / L are used to enter the bactericide into the produced water. Processing is carried out periodically, 1 day / 10-20 days or 6 hours / week (depending on the concentration of SSC).

The invention is illustrated in the drawing, which shows a diagram of the joint bactericidal and magnetic treatment of produced water.

The method is implemented as follows. First, based on the performance of the PPD system, the main elements of the scheme are selected: a magnetoactivator, a dosage block of an inhibitor-bactericide (standard BRH), and a technological scheme for joint processing is mounted. The implementation scheme includes a reservoir for collecting produced water 1 with an inlet pipe 2 and a dosage unit for bactericide 3 connected to the inlet pipe 2. At the outlet of the tank 1, a low pressure pump 4 is installed, connected through a low pressure pipe 5 and a magnetoactivator 6 with a buffer tank 7. Inlet high-pressure pump 8 is connected to the buffer tank 7, and the output to the injection well 9.

The scheme works as follows. Formation water is simultaneously supplied to reservoir 1 and, through dosage unit 3, an inhibitor-bactericide. In this case, the minimum dosage of the bactericide (50 mg / l) is chosen and gradually increased until the efficiency reaches not less than 97%. The produced water mixed with the bactericide is pumped through the magnetoactivator 6 to the buffer tank 7. The combination of powerful magnetic fields of the magnetoactivator 6 with activated bactericidal molecules destroys the remaining survivable SVB cells in the produced water, thereby eliminating the risk of biocorrosion of the equipment and the formation of hydrogen sulfide in the bottom hole of the injection well 9 and the reservoir where the treated water is pumped by a high pressure pump 8.

The bactericidal activity of the reagents was evaluated according to standard methods (RD 39-3-973-83. Methods for controlling the microbiological contamination of oilfield water by bacteria and evaluating the protective effect of reagents. Ufa. VNIISPTneft, 1983, 37 s).

The result of the joint treatment of produced water is controlled by a microbiological test for residual bacteria - a typical method of sowing crops that is widely used in oil production. The main indicators are the number of bacteria cells that survived after treatment, and the content of hydrogen sulfide H ₂ S after treatments of produced water.

The result of joint processing can also be checked by the content of hydrogen sulfide Н ₂ S in produced water. According to the results of control tests, increase or decrease the initial dose of the bactericide.

Table 1 shows the dosage data for typical reagents taken from review articles (Oil Industry magazine No. 2 for 2004, No. 1 for 2001, No. 4 for 2002).

Table 1 The regime of bactericidal treatment of PPD water with different reagents without magnetic treatment Brand of bactericide Dosage, g / m ³ The initial concentration of SVB, count / ml × 10 ³ The effectiveness of the bactericide, rel.% LPE-11V 500-600 one hundred thirty Troskil - 5407 500 450 95 SONCID8101 300-400 one 90 REEF 500-600 10 thirty Dms-hs 250-500 one hundred 98-100

Table 2 shows the results of laboratory tests of the action of a bactericidal inhibitor (DMS - HS) and magnetic treatment on the number of SVB cells in produced water of the RPD system of the White Tiger deposit of the Vietsovpetro joint venture.

The specified bactericidal inhibitor is a water-soluble mixture of a toxicant (poison for SVB), surfactants and other additives that enhance the action of toxicants and ensure the adsorption of the bactericide on the inner surface of the equipment, resistance to salts. It is a complex organic substance with its own magnetic moment.

When a bactericide inhibitor is used as a reagent, it contains, in addition to the toxicant, corrosion inhibitors - complex organic substances that create a protective film on the steel surface (imidazolines, amines, esters), which also have magnetoresistance, magnetic treatment enhances the adsorption properties of the molecules and contributes to an increase in the protective effect of the total corrosion, which is an additional beneficial effect of this proposal. General corrosion is caused not by SBB, but by salts and dissolved oxygen.

table 2 Dependence of the effect of the bactericide DMS-HS and magnetic treatment on the number of SVB cells in the formation water of the White Tiger deposit No. p / p Processing a sample of water The number of cells SVB, thousand cells / ml The death of SVB cells,% Bactericide Magnetic effect Source After processing Dose, mg / L Time, hour Processing time, s Field strength, kA / m one 0 0 1,2 450 450 300 33 2 0 0 1.4 450 450 200 55 3 0 0 1,6 450 450 160 64 four one hundred one 1,2 450 450 130 70 5 one hundred one 1.8 450 450 13.5 97 6 200 one 1,2 450 450 25 95 7 200 one 1.4 450 450 13.5 97 8 one hundred one 0 0 450 150 67 9 200 one 0 0 450 60 87 10 0 0 1,0 655 25 25 0 eleven 0 0 1.4 655 25 5 80 12 0 0 1,6 655 25 0.5 98 13 0 0 1.8 655 25 0 one hundred fourteen one hundred one 1.4 655 450 13.5 97 fifteen 250 one 0 0 2,5 0,045 98.2 16 250 one 0 0 450 0.9 99.8 17 500 one 0 0 2,5 0 one hundred eighteen fifty one 1.4 450 450 170 60

As follows from the table. 1 of the data, the rational parameters of the magnetic processing under the combined action of the bactericide and the magnetic field are in the following ranges: the magnetic field in the working gap is 450-655 kA / m, the magnetic processing time is 1.2-1.6 s. The required dose of bactericide was 100-200 mg / l, which is 2-2.5 times less than the dose required without magnetic treatment. The magnetic field has a bactericidal effect even without a bactericide, but it is possible to achieve high efficiency only with a low concentration of SVB (pos. 11-13) or the use of especially powerful bulky magnetic devices. With a significant concentration of SVB, it is difficult to achieve an efficiency of more than 90% (pos. 1-3 in Table 2). But saving bactericide is also achieved by increasing the period between chemical treatments.

Thus, the additional magnetic treatment of produced water makes it possible to significantly (2-2.5 times) reduce the dose of bactericide, while maintaining the processing efficiency at a high level (97%).

Claims (1)

A method of suppressing the growth of sulfate-reducing bacteria of formation water, comprising dosing a bactericidal inhibitor based on nitrogen-oxygen-containing organic compounds, characterized in that the formation water infected with bacterial microflora is additionally exposed to a magnetic field of 450-655 kA / m for 1.2-1, 8 sec