RU2249673C1 - Compound for removal of asphalt-resin-paraffin precipitations and hydrophobization of face-adjacent bed zone - Google Patents

Abstract

FIELD: oil industry.

SUBSTANCE: compound has processed cyclohexane fraction, processed tallic or rapeseed oil, additionally has modified high-dispersion polysyl-grade silica with following ratio of components in percents of mass: processed cyclohexane fraction 69.9-78.0, processed tallic or rapeseed oil 20.0-30.0, polysyl 0.1-2.0.

EFFECT: higher efficiency.

3 ex, 4 tbl

Description

The invention relates to the oil industry and can be used to remove asphaltene-tar-paraffin deposits (paraffin deposits) from oilfield equipment, wells and the bottom-hole formation zone, as well as to hydrophobize the bottom-hole formation zone in order to intensify oil production and increase oil recovery.

Known compositions for the removal of paraffin, which contain a hexane and ethylbenzene fraction (A.S. USSR No. 1620465, 09 K 3/00, B.I. 2, 1991) and a hexane fraction and light pyrolysis resin (A.S. USSR No. 1092164, C 09 K 3/00, B.I. 18, 1984).

The disadvantage of these compounds is their low efficiency in relation to paraffin in a wide range of asphaltenes, resins and paraffins.

A known composition for removing asphaltene-resin-paraffin deposits, which contains, wt.%: By-product of the petrochemical industry - hexane fraction or oil product - straight-run gasoline fraction - “reagent K-2” - 25 - 75, monoalkyl ether of polyethylene glycol based on primary fatty alcohols of the general formula C _n H _{2n + 1} O (C ₂ H ₄ ) _m H, where n = 10-18, m = 8-10, or ethoxylated isononylphenol with a degree of hydroxyethylation 9-12-0.5-5.0, a by-product of organic synthesis based on aromatic hydrocarbons - the rest (RF Patent 2131901, C 09 K 3/00, E 21 B 37/06, B.I. 17, 1999).

The disadvantage of this composition is the low boiling point of the hexane and gasoline fractions, the use of components containing aromatic hydrocarbons that have a harmful effect on people and the environment, as well as insufficient effectiveness for paraffin waxes with a high content of paraffins, resins and asphaltenes.

Closest to the proposed composition is a composition for removing paraffin, containing a mixture of hydrocarbons, in wt.%: Spent cyclohexane fraction - 70-80, spent tall or rapeseed oil - 20-30 (RF Patent 2185412, С 09 К 3/00, Е 21 B 37/06, publ. 20.07.02).

The composition has good dissolving ability in relation to paraffin wax with a high content of paraffins, asphaltenes and resins. However, the composition has insufficient detergent, emulsifying and stabilizing effect of the contaminated surface in relation to asphaltene-tar-paraffin deposits with a high content of paraffins, asphaltenes and resins.

The objective of the invention is to increase the washing, emulsifying and stabilizing effects of the contaminated surface in relation to asphaltene-resin-paraffin deposits with a high content of paraffins, asphaltenes and resins, as well as an increase in oil-displacing properties of the composition by increasing the hydrophobization of the formation rock.

The problem is solved in that the composition for removing asphaltene-tar-paraffin deposits and hydrophobization of the bottomhole formation zone, containing spent cyclohexane fraction, spent tall oil or rapeseed oil, characterized in that it additionally contains modified highly dispersed silica grade Polysil in the following ratio of components, wt.%:

Spent cyclohexane fraction 69.9-78.0

Waste tall or rapeseed oil 20.0-30.0

Polisil 0.1-2.0

The spent cyclohexane fraction is a waste product of the production of polyethylene products containing, in wt.%: Cyclohexanone - 71.4-75.0, heptanon-2 - 4.6-5.29, cyclohexane 1.43-1.71, cyclopentanone 2 40-2.86, cyclohexanol 13.1-14.8, cyclohexene 0.70-0.86, water 2.0-3.0.

Spent tall oil mainly contains, wt.%: Fatty acids (oleic, linoleic, etc.) 30-60, resin acids 30-60, neutral substances 8-20, oxidized substances 4-10, moisture up to 8.0.

Used rapeseed oil, wt.%: Oleic acid up to 20.0, erucic acid 56.0-65.0, linoleic acid up to 14.0.

The mixture of spent components is a yellow oily liquid with a density at 20 ° C of 944 kg / m ³ with a water content of 2.0% and a flash point in a closed crucible of 45.5 ° C.

As Polysil, chemically modified silicas (SiO ₂ ) are used, which, depending on the modification method, may have hydrophobic (Polysil-P1) or diphilic (Polysil-DF) properties.

Polysil is a trademark of chemically modified silicas (SiО ₂ ) (Trademark “Polysil”, certificate No. 199999 of December 6, 2000).

Polysil-P1 has strong hydrophobic and organophilic properties, is a highly dispersed powder based on silicon dioxide, chemically modified with an organosilicon compound, has a bulk density of 0.035-0.14 g / cm ³ , particle size 0.005-0.04 μm, specific surface area 300 m ² / g, effective contact angle for the surface treated with Polysil-P1 140-170 °, operating temperature range - 60 - + 180 ° С, hydrophobicity - 99% (TU 2169-001-0470693-93).

Polysil-DF has the properties of a solid non-ionic surfactant due to the chemical structure of the grafted surface layer, has emulsifying properties, has a bulk density of 0.035-0.14 g / cm ³ , particle size 0.005-0.04 μm, specific surface area 300 m ² / g, effective wetting angle for the surface treated with Polysil-DF, 0 °, range of working temperatures - 60 - + 180 ° С, degree of hydrophobicity - 100% (TU 2311-002-04706-93).

Chemically modified fine powder of the Polysil brand is a chemically inert powder that does not have a harmful effect on humans and the environment, in accordance with the “Primary Toxicological and Hygienic Certificate of the New Compound” approved by the Ministry of Health of the Russian Federation, this class of materials is classified as 4- according to GOST 12.007-76 that class of low hazard substances. Storage conditions Polysil: dry room at a temperature from - 50 to + 50 ° С.

Unlike the prototype, the claimed composition additionally contains a new component - chemically modified fine silica brand Polysil.

Highly dispersed hydrophobic silica of the Polysil brand, introduced into the composition, having submicron particles, easily penetrates the pores and microcracks of the formation, changes the surface energy (wettability). This qualitatively changes the filtration characteristics of the reservoir for both water and oil.

The proposed composition containing highly dispersed hydrophobic silica with a degree of hydrophobicity of 99-100%, largely hydrophobizes the surface of the rock. Hydrophobization of the rock surface occurs as a result of the finely dispersed material being fixed in the pore volume due to its small particle size and due to adhesion forces, as well as by changing the wetting angle to 170-178 ° and lowering the surface tension.

The proposed composition may contain modified silica brand Polysil-DF. Due to the structure of the grafted surface layer, Polysil-DF has the properties of a solid nonionic surfactant.

As a result of fixing in the pore volume due to its small particle size and due to the adhesion forces, Polysil-DF significantly reduces the surface tension at the water-rock-oil interface, increasing the phase permeability of the fluid.

Adding Polisil-DF brand material to the proposed composition enhances the washing effect of contaminated surfaces and leads to the emulsification of grease and oil contaminants, dispersion and stabilization of particulate matter (AFS).

In the proposed composition as a component that enhances the hydrophobic properties of the composition, use modified hydrophobic silica brand Polysil-P1. Chemical modification of the surface of silicon dioxide is performed by an organosilicon compound of the general formula Cl _4-n SiR _n , where n = 1-3; R = H, methyl, ethyl, Cl is methyl, phenyl, followed by treatment with a compound selected from the group consisting of tetramethoxylan or tetraethoxylan or polymethylsilazane.

Used tall oil mainly contains fatty carboxylic acids (oleic, linoleic, etc.), resin acids, and used rapeseed oil contains oleic acid, linoleic acid, which are oil-soluble surfactants.

In addition, the composition contains a cyclohexane fraction, in which alicyclic alcohol - cyclohexanol, as well as alicyclic ketones - cyclohexanone, heptanone and cyclopentanone are present. When mixed with tall or rapeseed oil, they form complex mixtures of derivatives of tall or rapeseed oil acids in a hydrocarbon solvent, which are effective oil-soluble surfactants.

The above fatty carboxylic acids and complex mixtures of derivatives of tall or rapeseed oil acids in a hydrocarbon solvent are effective emulsifiers.

When injected into a water-permeable oil reservoir, the above oil-soluble surfactants form inverse emulsions (water-in-oil type) when mixed with produced water.

The prospectivity and high efficiency of reverse emulsions is due to a number of their positive qualities. Firstly, the dispersed nature of reverse emulsions allows them to be selectively filtered into the most permeable zones of the formation, secondly, the ability to thicken and structure during mechanical mixing with formation water during filtration into the depth of the formation, and vice versa, to dilute when dispersed with oil, which ensures their high selectivity, thirdly, the presence in their composition of oil-soluble surfactants with high adhesion to the hydrophilic rock of the formation in water-washed areas gives them the ability as when moving along the filtration onnym channels, and after decomposition of the skeleton of the collector hydrophobized with an increase in its permeability to oil and water to reduce.

The presence of highly dispersed hydrophobic silica in the above emulsions increases their viscosity, stabilizes and hydrophobizes the emulsions.

With an increase in the concentration of highly dispersed hydrophobic silica introduced into the composition, the stabilizing and phobizing effect of it increases, which makes it possible to obtain stable emulsions.

The presence of calcium and magnesium chloride, as well as other electrolytes in formation water increases the stability of emulsions with increasing temperature. This effect is mainly affected through chemical transformations of the emulsifier in the composition of the emulsion and changes in the composition of the adsorption layers. The presence of metal cations (calcium, magnesium, etc.) promotes the exchange reaction of the formation of metallic soaps of higher carboxylic acids present in the emulsifier, which leads to a sharp decrease in interfacial tension, a more effective washing, emulsifying and stabilizing effect of the contaminated surface with respect to ARPD with high in paraffins, asphaltenes and resins.

The proposed composition containing the spent cyclohexane fraction, spent tall or rapeseed oil and highly dispersed hydrophobic silica of the Polisil brand has a high dissolving ability, and due to the increase in the washing, emulsifying and stabilizing ability of it with respect to ARPD, it will be more efficient to use it to remove ARPD with high the content of paraffins, asphaltenes and resins, and due to hydrophobization of the formation rock, that is, an increase in the relative permeability of the formation for the hydrocarbon phase of water compared to an increase oil-displacing properties of the composition.

Studies of the effectiveness of the dissolution of paraffin were carried out by the method of “cold rod” on the installation, simulating the work in the well (according to the prototype). About 1 g of AFS is applied to the metal rod. 50 ml of the composition is poured into the vessel, which is prepared by mixing the starting components at a temperature of 40-50 ° C for 15 minutes. A rod suspended by a flexible thread through a pulley performs reciprocating movements in a vertical plane using an electric motor. As a result of these movements, the sediment is flushed with the studied composition.

Compositions of paraffin deposits having a high content of paraffins, asphaltenes and resins selected at the Chapaevskneft and Kineleneft oil fields of the Samara Region were selected for testing.

The compositions are given in table. 1.

Studies of the effectiveness of the dissolution of ASPO compositions having a high content of paraffins, asphaltenes and resins have been carried out.

The results of the effectiveness of the dissolution of paraffin in the proposed composition in comparison with the prototype are presented in table. 2 and 3 at a temperature of 20 ° C.

The data table. 2 and 3 show that the proposed composition at different ratios of components has a high dissolving ability with respect to paraffin wax with a high content of paraffins, asphaltenes and resins.

In addition, the proposed composition has the best oil-displacing properties in comparison with the prototype. Data on filtration through water-washed oil-saturated core (simulation of processing water-washed oil-saturated zone of the formation) of the compositions of the proposed composition and prototype are presented in table. 4.

Example. 1. Prepare a composition according to the proposed composition: in 74 g of the spent cyclohexane fraction, 25 g of waste tall oil are added with stirring, then 1 g of polysil-DF silica is added in small portions with stirring.

The proposed composition is filtered through a washed oil-saturated core in a filtration unit (simulation of processing water-washed oil-saturated zone of a formation) in order to increase the oil-displacing ability of the composition under conditions of additional washing out of residual oil on a linear model of a homogeneous formation.

The linear model is a stainless steel core with a length of 220 mm and an internal diameter of 32 mm, which is filled with a mixture containing 95% silica sand and 5% montmorillonite clay. The model is saturated with water under vacuum, and the column permeability to water is determined by weight.

After that, oil is injected into the model under pressure until clean (without water) oil appears at the outlet, the initial oil saturation is determined, which is 63.5-71.0%. In the filtration works, natural oil is used with a density of 842 kg / m ³ and a dynamic viscosity of 8.5 MPa · s at 20 ° C. The initial displacement is carried out with water (three pore volumes) and the coefficient of oil displacement by water is determined. After that, one pore volume of the prepared composition of the proposed composition and three pore volumes of water are filtered through the model, the growth and the total oil displacement coefficient are determined.

The results of filtration studies of oil-displacing ability of the compositions of the proposed composition are presented in table. 4.

Example. 2. Prepare the composition according to the prototype: in 75 g of the spent cyclohexane fraction, 25 g of waste tall oil are added with stirring.

The prepared composition is filtered through a washed oil-saturated core in a filtration unit (simulation of processing a water-washed oil-saturated zone of a formation) in order to increase the oil-displacing ability of the composition under conditions of additional washing out of residual oil on a linear model of a homogeneous formation.

Through the above core (see example 1), one pore volume of the prepared prototype composition and three pore volumes of water are filtered, the growth and the total oil displacement coefficient are determined.

The results of filtration studies of oil-displacing ability of the compositions of the prototype are presented in table 4.

Example. 3. Prepare a composition according to the proposed composition: in 69 g of the spent cyclohexane fraction, 30 g of used rapeseed oil are added with stirring, then 1 g of polysil-P1 grade silica is added in small portions with stirring.

The proposed composition is filtered through a washed oil-saturated core in a filtration unit (simulation of processing water-washed oil-saturated zone of a formation) in order to increase the oil-displacing ability of the composition under conditions of additional washing out of residual oil on a linear model of a homogeneous formation.

Through the above core (see example 1), one pore volume of the prepared composition of the proposed composition and three pore volumes of water are filtered, the growth and the total oil displacement coefficient are determined.

The results of filtration studies of the oil-displacing ability of the compositions of the proposed composition are presented in table 4.

The data of tables 1-3 show that the proposed composition has a high dissolving ability in relation to paraffin wax with a high content of paraffins, asphaltenes and resins.

In addition, filtration studies showed that the proposed composition has higher oil-displacing properties compared with the prototype. The increase in the displacement coefficient of the proposed composition increases from 0.24 to 0.30 (see table 4.).

When the content in the proposed composition of Polysil is less than 0.1 wt.%, The increase in the oil displacement coefficient differs little from the prototype, therefore, the concentration of 0.1 wt.% Polysil is taken as the minimum content in it. The upper limit of the content of Polysil in the proposed composition is 2.0 wt.% Due to the element of sufficiency of the achieved result, since an increase in the content of Polysil to 2.5 wt.% Leads to a slight increase in the growth rate of oil displacement (see table 4).

Technical result: as a result of the injection of the proposed composition containing spent cyclohexane fraction, spent tall oil or rapeseed oil and additionally highly dispersed hydrophobic silica of the Polisil brand, which has a high dissolving ability with respect to ARPD, there is an increase in the washing, emulsifying and stabilizing effect of the contaminated surface with respect to particles of solid particles pollution (AFS), significantly reduced water cut and an increase in oil production, which is achieved due to increase the water-repellency of the reservoir rock.

The technology for preparing the composition according to the proposed composition is simple.

To the spent cyclohexane fraction in the amount of 69.9-78.0 wt.%, The spent tall or rapeseed oil in the amount of 20-30 wt.% Is added with stirring, then polysil silica is introduced in small portions in the amount of 0 1-2.0 wt. %, mix thoroughly and the proposed composition is ready for use.

Table 1 No. p / p The composition of paraffin, wt.% Paraffins asphaltenes + resins 1 36.7 63.3 2 70.9 29.1 3 73.6 26,4 table 2
The results of the effectiveness of the dissolution of paraffin No. p / p Ratio
AFS - composition The dissolution efficiency,% 30 min 60 min 90 min 1 1:50 51.3 87.1 97.7 2 1:50 50.8 86.2 97.4 3 1:50 50,5 83.8 96.5 Note: the composition in table 2 of table 3 example 4.

Claims (1)

Composition for removing asphaltene-tar-paraffin deposits and hydrophobization of the bottom-hole formation zone, containing spent cyclohexane fraction, spent tall oil or rapeseed oil, characterized in that it additionally contains modified highly dispersed silica of the Polisil brand in the following ratio of components, wt.%: Spent cyclohexane fraction 69.9-78.0 Waste tall or rapeseed oil 20.0-30.0 Polisil 0.1-2.0