RU2632845C1 - Solvent of asphalt-resin-paraffin deposits - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention can be used to dissolve and remove asphalt-resin-paraffin deposits (ARPD) from the surface of the downhole equipment, in reservoirs and oil-gathering reservoirs. The solvent of asphalt-resin-paraffin deposits contains aromatic and aliphatic hydrocarbon solvents and a nonionic surfactant, which is a depressant-dispersing additive (DDA) containing the "Yalan-E2" emulsifier and an ethylene-alpha-olefin copolymer with the molecular weight of 500 to 100,000 or polyalkyl acrylate, with the following ratio of components, wt %: solvents - 97-98, depressant-dispersing additive - 2-3.

EFFECT: increasing the detergent, solvent, dispersing capacity of the solvent.

3 cl, 1 tbl, 3 ex

Description

The invention relates to the oil and gas industry and can be used to remove and dissolve asphalt-resin-paraffin deposits (AFS) from the surface of downhole equipment, in tanks and oil collectors.

A known composition for removing asphaltene-resin-paraffin deposits (RF patent No. 2323954, publ. 05/10/2008), containing in vol.%: At least one specified block copolymer of 0.5-5.0, aromatic hydrocarbon 30, aliphatic hydrocarbon - the rest.

The disadvantage of this composition is the low efficiency of the dissolution of paraffin deposits with a high content of asphaltenes.

A known composition for removing paraffin (patent of the Russian Federation No. 2183650, publ. 06/20/2002), containing vol.%: Aliphatic hydrocarbons 50-85, polar non-electrolyte 2-5, nonionic surfactant 1-2, cationic surfactant 1-2, solvent - absorbent-A-2 heavy 7-22, aromatic hydrocarbons the rest.

The disadvantage of this composition is its low efficiency at low temperatures.

A known composition for removing asphalt-resin-paraffin deposits (RF patent No. 2173328, publ. 09/10/2001), containing an aromatic solvent, nonionic surfactant OP-7 or OP-10, anionic surfactant (sulfonol) in relation to OP -7 or OP-10 as 1: 3.5 in the following ratio of components, wt.%: OP-7 or OP-10 - 16-35, sulfonol - 4.5-10.3, aromatic solvent - the rest.

The disadvantage of the composition is not enough high-quality cleaning of the surface of the tubing and piping from paraffin. The solvent capacity is lower compared to the proposed solvent.

A known composition for removing asphaltene-resin-paraffin deposits (RF patent No. 2159583, publ. 04/27/1999), used to remove paraffin from the bottomhole formation zone, flow lines, oil reservoirs and oilfield equipment of oil producers and oil refineries, containing, vol.%: Al hydrocarbons 36-78; aromatic hydrocarbons - 20-60; polar non-electrolyte - 0.5-4; surfactant - demulsifier - 0.01-1.0; pH regulator - the rest.

The disadvantage of the composition is the low efficiency of the removal of paraffin in difficult conditions, this composition is also characterized by insufficient dissolution of paraffin with a high content of paraffins with a high molecular weight.

A known composition for removing asphaltene-resin-paraffin deposits (RF patent No. 2165953, publ. 04/27/2001), adopted for the prototype, containing in vol.%: Aliphatic hydrocarbons 25-85; polar non-electrolyte 2-5; nonionic surfactant 1-2; cationic surfactant 1-2; aromatic hydrocarbons rest.

The disadvantage of this known composition is the low removal efficiency of heavy paraffin. This composition is not intended for deposits at low temperatures.

The technical result is the creation of an effective solvent based on hydrocarbon compounds, which includes a depressant-dispersing additive (DDP), which can reduce the pour point of oil and the precipitation of paraffin crystals during oil production, transportation and storage. When using DDP, there is an increase in the washing, dissolving, dispersing abilities of the solvent used to remove paraffin in difficult conditions.

The technical result is achieved by the fact that as a nonionic surfactant using a depressant-dispersing additive containing an emulsifier "Yalan-E2" and a copolymer of ethylene with alpha-olefins with mol. weighing from 500 to 100,000 or polyalkyl acrylate, in the following ratio of components, wt.%:

solvents 97-98;

depressant-dispersant additive - 2-3.

The solvent of asphalt-resin-paraffin deposits is illustrated by the following figures:

FIG. 1 is a diagram of the effectiveness of the solvent before and after the application of DDP according to the methods of "baskets" and on the installation "Cold Rod" at a temperature of + 37 ° C;

FIG. 2 is a diagram for determining the effectiveness of the solvent by the method of "baskets" in static mode at a temperature of 20 ° C;

FIG. 3 is a diagram for determining solvent efficiency by the “baskets” method in dynamic mode using magnetic stirrers at a temperature of 20 ° C.

As hydrocarbon compounds can be selected: benzene, toluene, xylene, ethylbenzene, petroleum distillates. The presence of aromatic hydrocarbons makes it possible to efficiently dissolve asphalt-resinous substances, which are slightly or insoluble in paraffin hydrocarbons.

The MP-172 DP depressant-dispersant additive according to STO 22650721-001-2015 is a depressant additive composition based on an ethylene-alpha-olefin copolymer that can lower the pour point of oil and an amide-type dispersant that prevents the growth of paraffin crystals during production, transport and storage of oil.

As the dispersant of amide type paraffins in the composition of “MP-172 DP”, the “Yalan-E2” reverse emulsifier of water-in-oil emulsions with rev. 1, grade A (conc.), Manufactured according to TU 2458-001-22650721-2009, which is a product of the interaction of unsaturated fatty acids and complex ethyleneamines, amino alcohols and their mixtures, in the following ratio of components in wt.%:

- Depressant additive based on polyolefins, or polymethacrylates, - 50-95;

- Emulsifier "Yalan E-2" grade A (conc.) - up to 100.

The mechanism of action of the depressant-dispersing additive is aimed at creating a proppant effect in relation to the ARPD, increasing the area available for dissolution and the efficiency of removing the ARPD from the equipment surface. DDP reduces the strength of the armor shells of oil-water emulsions stabilized with asphaltenes, and affects the rheological characteristics of oil.

Studies to assess the washing, dissolving and dispersing abilities of the solvent were carried out according to the "Methodology for determining the effectiveness of reagents for removing paraffin wax" (the "baskets" method), proposed by NIIneftepromkhim, in static and dynamic modes. Paraffin paraffin paraffin test sample (asphaltenes - 0.52-1.07%; paraffins - 50.5-78.3%; resins - 2.55-7.68%; solids - 0.13-3.71% ) in the form of balls with a diameter of 10 mm in a steel basket with a cell size of 1.0 × 1.0 mm was placed in a sealed cell with a volume of 150 cm ³ , where the developed solvent was poured in the ratio of 10 g per 1 g of ARPD, so that the solvent completely covered the AFS sample . At certain intervals, the baskets were removed from the solvent and kept in air until the mass was constant.

The washing ability of the solvent is defined as the ratio of the difference between the initial mass of the ARPD sample placed in the basket and the mass of the ARPD remaining in the basket after the experiment, to the initial mass of the sample. The higher the value of this indicator, the higher the efficiency of the solvent. The dispersing ability of a solvent is defined as the ratio of the mass of the ARPD residue on the filter to the initial mass of the ARPD sample in the basket. It characterizes the ability of a solvent to break down paraffin deposits into smaller fragments. The solvent capacity of a solvent is defined as the ratio of the difference between the mass of dissolved and dispersed deposits to the initial mass of the ARPD sample.

When using the “baskets” methodology, it must be taken into account that the solvent acts on paraffin deposits from all sides, while under borehole conditions, contact from all sides is not detected.

Therefore, studies were conducted on the process of removing ARPD from a metal surface at the Cold Rod installation to ensure a "wall effect" and approximate the conditions for the formation of ARPD to the borehole ones.

The bath temperature was set at + 37 ° С (reservoir temperature of the studied field), the temperature of the cold core was + 2 ° С (average temperature of tubing walls in winter).

A paraffin sample was previously melted. Then the cold rod was lowered into a cup with a melted paraffin sample for 2 minutes. When AFS is applied on a metal surface in molten form, paraffin crystals adhere to the surface due to the difference in deposition temperature and metal. Then cold rods were lowered into solvents at various concentrations of components for a certain period of time. The maximum residence time of the cold rod in the solvent was 24 hours. The washing, dissolving and dispersing abilities of the solvent were evaluated.

To prove compliance of the invention with the criterion of "industrial applicability" and illustrate the developed solvent, examples of its preparation at various concentrations of reagents are given below. The range of selected reagents is presented in table 1.

Example 1. An AFS sample was heated to a softening temperature, after which balls 10 mm in diameter were made. Then, ARPD in a steel basket with a mesh size of 1 × 1 mm was placed in an airtight flask with a volume of 150 cm ³ with a solvent in the ratio of 10 g of solvent per 1 g of ARPD until the deposits were completely covered with reagent.

The solvent is prepared by simply compounding the calculated amounts of the components in a separate container. Toluene (40 wt.%) Was mixed with diesel fuel (58 wt.%). DDP was heated without boiling. Then in the percentage of 2 mass. % added to toluene and diesel. The resulting solvent was thoroughly mixed for 10 minutes to a homogeneous mass at room temperature.

Example 2. An AFS sample was also prepared as in example 1. Then it was placed in an airtight cell with a solvent. The solvent was prepared, as by analogy with example 1. The components of the solvent were selected in the following percentage ratio, wt.%: Toluene - 48.5; diesel fuel - 48.5; DDP-3. The resulting composition is thoroughly mixed for 10 minutes until a homogeneous mass at room temperature.

Example 3. The procedure for preparing an AFS sample is the same as in examples 1 and 2. The solvent was prepared as follows. Toluene with diesel fuel (60 and 37.5 wt.%) Was mixed, then a depressant-dispersant additive (2.5%) was added, brought to a liquid state. The resulting composition is thoroughly mixed for 10 minutes until a homogeneous mass at room temperature.

Laboratory studies were carried out to determine the optimal concentrations of solvent components for the removal of paraffin. The highest solvent efficiency is observed when 55-60% toluene and 40-45% diesel fuel are added. However, based on the economic feasibility and availability of toluene, the optimal ratio of diesel fuel and toluene, at which a synergistic effect is observed, is the content of these components in a proportion of 50:50. The optimal concentration of DDP was 3 wt.%. After adding DDP to the solvent, there is a significant increase in its washing and dispersing abilities, thereby increasing the surface activity of the solvent and the dispersion effect of ARPD (Fig. 1). Reducing the surface tension, the solution moistens the AFS sample, penetrating into cracks and pores, while the adhesion of its particles decreases.

Further, studies to determine the effectiveness of the solvent for removing paraffin deposits in downhole equipment were carried out based on the optimal concentrations of the reagent, taken from example 2. The main parameters of efficiency were determined at 20 and 37 ° C: washing, dispersing and dissolving abilities (Fig. 1-3).

The experiments carried out on the Cold Rod facility showed results comparable with those of the baskets. The washing and dispersing abilities of the solvent when adding a depressant-dispersing additive, calculated using the Cold Rod installation and the “baskets” technique, are 2 times higher than the experimental results without adding surfactants to the solvent. However, the solvent capacity calculated by the “baskets” technique decreased after the addition of the additive. According to the results of laboratory experiments conducted by the method of "baskets" and on the installation "Cold Rod", it was found that the optimal processing time was 8-10 hours.

Thus, based on FIG. 1-3, the developed solvent is characterized by high washing and dispersing abilities with respect to asphalt-resin-paraffin deposits, which allows us to recommend it for removing these deposits in oil wells (for flushing downhole equipment).

Claims (2)

Solvent for asphalt-resin-paraffin deposits, containing aromatic and aliphatic hydrocarbon solvents and a nonionic surfactant, characterized in that as a nonionic surfactant, a depressant-dispersant additive containing an emulsifier "Yalan-E2" and an ethylene-alpha-olefin ethylene molecular copolymer is used weighing from 500 to 100,000 or polyalkyl acrylate, in the following ratio of components, wt.%: solvents 97-98 depressant-dispersant additive 2-3

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