RU2242597C2 - Oil production composition - Google Patents

Abstract

FIELD: oil and gas production.

SUBSTANCE: invention provides oil production composition serving to limit water inflow into producing wells and thereby to increasing recovery of oil. Composition is made up of "Neftenol NZb", 10-15%, synthetic latex, 2-5%, and liquid hydrocarbon.

EFFECT: increased efficiency of production of oil for watered formations in late development stage due to increased stability of composition, increased oil-driving property, and expanded coverage of formation.

2 tbl, 3 ex

Description

The invention relates to the oil industry, and in particular to compositions for oil recovery in order to limit water inflow to production wells and increase oil recovery.

It is known to use a composition containing an emulsifier based on esters of oleic, linoleic, linolenic, resin acids and triethanolamine (Neftenol NC), liquid hydrocarbon, calcium chloride, and the rest water (see US Pat. No. 2110675, E 21 B 43) to increase oil recovery. / 22, 1997).

The disadvantages of this composition are the low aggregate stability and insufficient displacement ability of the emulsion formed when mixed with water in the washed zones of the formation.

The closest in technical essence and the achieved effect is a composition containing an emulsifier based on esters of oleic, linoleic, linolenic, resin acids and triethanolamine (Neftenol NC), oil and water (see US Pat. No. 2,166,617, E 21 B 43/22, 1997).

The disadvantage of this composition is the low efficiency due to the insufficient increase in the coverage of the formation due to the low viscosity and stability of the emulsion formed when mixed with water in the washed zones of the formation.

The present invention is based on the task of creating a more effective composition for oil recovery by increasing the stability of the emulsion composition, increasing its oil-displacing ability, which allows to increase oil recovery by increasing the coverage of the formation by exposure.

The problem is solved in that the composition for oil recovery containing oil-soluble surfactant and liquid hydrocarbon according to the invention as an oil-soluble surfactant contains a hydrocarbon dispersion of esters of oleic, linoleic, linolenic, as well as resin acids and colloidal dispersed phase - Neftenol-NZb and optionally synthetic latex in the following ratio of components, wt.%:

Oil soluble surfactant

substance-Neftenol-NZb 4-15

Synthetic latex 2-5

Liquid hydrocarbon Else

Salient features of the developed composition are the following.

The use as an oil-soluble surfactant of a hydrocarbon dispersion of esters of oleic, linoleic, linolenic, resin acids and the colloidal dispersed phase-emulsifier Neftenol NZb.

The introduction of Neftenol NZb into the microemulsion allows, firstly, as in the prototype, to regulate the hydrophilic-lipophilic balance of the system; secondly, it helps to increase the viscosity and improve the rheological properties of the emulsion composition due to the presence of a colloidal hydrocarbon dispersed phase in it. Ultimately, this helps to improve the water-insulating properties of the microemulsion, increase the coverage of the formation by impact and increase oil recovery. The specified ratio of the components improves the rheological properties of the composition and improves the stability of the resulting emulsion, prevents its early destruction in the reservoir.

The introduction of synthetic latex into the composition allows stabilization to be achieved and contributes to the additional structuring of the composition, which is a reverse emulsion, and as a result, a multiple emulsion is formed with high structural and rheological properties.

Emulsifier Neftenol NZb is a hydrocarbon dispersion of esters of oleic, linoleic, linolenic, as well as resin acids and a colloidal dispersed phase. Neftenol NZB is produced according to TU 2458-057-17197708-01. Appearance - oily viscous dispersion from light brown to brown.

Synthetic latex is a direct emulsion of hydrocarbon (hydrocarbon-swelling) rubber oligomers with a particle size of 0.05-2 microns (25-50%) in an aqueous medium stabilized by water-soluble surfactants. As a synthetic latex, SKMS-30ARK latex according to TU 2294-070-16810126-98 or any other can be used.

As a liquid hydrocarbon, oil is used - crude oil produced in the field. The recovered oil is used because of its low cost and availability, and also because of its composition similar to the composition of oil contained in the reservoir. In addition to oil, you can use stable gasoline, gas condensate, diesel fuel, spent diesel fuel, as well as a wide fraction of light hydrocarbons.

The composition is prepared by mixing the components to obtain a homogeneous solution in the factory or directly in the field.

The achieved positive effect is ensured by the fact that when the composition is mixed with produced water, a multiple emulsion is formed with a high viscosity, which is structured with further advancement and contributes to the creation of effective resistance to the flow of injected water in the washed zones of the formation with subsequent clogging. The introduction of synthetic latex, which is a direct emulsion of hydrocarbon oligomers in an aqueous medium, stabilized by water-soluble surfactants, allows stabilization and additional structuring of the composition, which is an inverse emulsion, and, as a result, a multiple emulsion with high structural and rheological properties is formed.

The effectiveness of this composition was determined by the degree of decrease in the permeability of the porous medium and the increase in oil recovery by a known method.

Example 1. Prepare composition No. 1. 4 ml of Neftenol NZb, 2 ml of synthetic latex, 4 ml of oil are poured into the flask and stirred for 10 minutes. Similarly prepare compositions No. 2-6 (table. 1). All formulations are checked for stability of the resulting microemulsions for 35 days. The inventive compositions are more effective in aggregate stability (more than 30 days) compared with the prototype (17 days).

Example 2. Oil-displacing properties are determined under the conditions of additional washing out of residual oil on a bulk model of a formation 40 cm long and 3 cm in diameter. The model is saturated with water under vacuum, the water permeability of the model is determined by a weight method (K ol = 3.01 μm ² ). Then, oil is injected into the model under pressure until anhydrous oil exits from it and the initial oil saturation is determined, which is 64.3%. Next, 3 pore volumes of water are pumped. After flooding, the residual oil saturation is 26.7%, the oil displacement coefficient by water is 0.63. Then, one pore volume of the composition of the following component composition is pumped through the model, wt.%: Neftenol NZb - 10.0; synthetic latex - 5.0: oil - the rest. Squeeze the composition with three volumes of produced water. After that, the residual oil saturation is 20.1%, the total oil displacement coefficient is 0.89, and the increase in the displacement coefficient is 0.26. Similarly, experiments are conducted with compositions of another component composition. The results of experiments on the displacement of oil through a reservoir model are given in table 2. The increase in displacement coefficient is 0.26-0.36 against 0.2 in the prototype, that is, 1.55 times higher.

Example 3. The water-insulating ability of the proposed composition is also investigated on a bulk model of the same size as in example 2, in conditions close to the reservoir. Filtered water is filtered through the model with a salinity of 150 g / l at a constant volumetric flow rate of 5 m ³ / h until the pressure drops stabilize and oil displacement ceases. Then, a microemulsion rim of the following component composition is pumped through the model, wt.%: Neftenol NZb-10.0; synthetic latex - 5.0: oil - the rest. The filtration is stopped, held for 8 hours and the formation water is again filtered until the pressure drops on the reservoir model stabilize and oil displacement ceases. According to Darcy's law, the values of the relative change in permeability are determined by the pressure model according to the reservoir model. The results of the experiments (Table 2) show that the proposed composition can significantly increase the degree of decrease in permeability (by 14%) in the water-saturated part of the formation, thereby increasing the coverage of the formation by water flooding and increasing oil recovery.

From the data presented in table 2, it can be seen that the proposed composition allows to increase the degree of decrease in permeability of the water-saturated part of the formation, thereby increasing the coverage of the formation by water flooding and increase oil recovery.

The composition is simple and technologically advanced, it is highly effective for enhancing oil recovery in flooded formations that are in the late stages of development.

Claims (1)

Composition for oil recovery containing an oil-soluble surfactant, a liquid hydrocarbon, characterized in that as an oil-soluble surfactant it contains a hydrocarbon dispersion of esters of oleic, linoleic, linolenic, resin acids and a colloidal dispersed phase - Neftenol NZb and optionally synthetic latex in the following ratio of components, wt. %: Oil soluble surface -active substance Neftenol NZb 4-15 Synthetic latex 2-5 Liquid hydrocarbon Else