RU2109939C1 - Compound for limitation of brine water inflow - Google Patents

Abstract

FIELD: oil and gas production industry. SUBSTANCE: compound for limitation of brine water inflow makes for reducing permeability of water-washed intervals in oil bed and for levelling injectivity profile of injection well. Compound has following content of components, mass%: petroleum product, 3-10; non-ionogenic surface-active matter, 0.5-5; wood flour, 0.1-5; water, the balance. EFFECT: higher efficiency. 1 cl, 2 tbl

Description

 The invention relates to the oil industry and can be used to limit the influx of formation water in injection wells during the development of oil fields by water flooding in order to increase oil recovery.

 A known composition for limiting the influx of formation water into injection wells, including a dispersed filler - silicon dioxide, a hydrocarbon solvent and a dispersion stabilizer [1].

 The disadvantages of the composition are low efficiency when used on highly permeable heterogeneous formations that are in the late stages of development, and when dagger breakthroughs of water to production wells.

 Known composition, including dispersed filler - soot, kaolin or talc, nonionic surfactant (nonionic surfactant) and lignosulfonate [2]. The composition, when injected into the reservoir, provides coalescence of residual oil droplets and reduces the permeability of water-washed intervals.

 The main disadvantage of the composition is the low efficiency on highly permeable porous and fractured reservoirs, due to the weak blocking effect and the removal of dispersed filler due to the small particle size.

The closest technical solution taken as a prototype is the composition [3], containing, wt.%:
Oil product - 5.5-65.0
Filler (chalk) - 0.1-7.0
Bentonite powder - 3.0-7.0
Stabilizer - 0.1-1.5
Surfactant - 0.1-1.5
Water - 6.0-62.1
The main disadvantage of the composition is the low efficiency when used on highly permeable porous and fractured reservoirs, due to the low penetration ability of the composition into the reservoir volume.

 The objective of the invention is the mudding of highly permeable intervals and fractures of the reservoir, aimed at limiting the influx of formation water and aligning the injectivity profile of the injection well.

 The problem is solved by using the developed composition, which effectively blocks water breakthrough both near the near-wellbore zone of the formation (PZP) of the injection well and in the volume of the formation.

The essence of the developed composition to limit the influx of formation water, including oil, surfactant and water, is that the composition contains a nonionic surfactant and additionally wood flour in the following ratio, wt.%
Oil product - 3-10
Nonionic surfactant - 0.5-5
Wood flour - 0.1-5
Water - Else
In this case, as a nonionic surfactant, an oil- or oil-water-soluble nonionic surfactant is used, for example, emulsion, neftenol, neonol AF _9-6 9 or OP-7.

 The composition after injection into the reservoir penetrates the most washed intervals of the reservoir and the place of water breakthrough. At the same time, due to the viscous properties of the composition and the largest particles of wood flour, redistribution of filtration flows and colmatation of pores and cracks near the bottomhole formation zone occur. Due to the high sedimentation stability of the composition due to the presence of an oil product and an oil-soluble nonionic surfactant, smaller particles of wood flour penetrate into the reservoir volume, being distributed along the water injection line towards production wells. In this case, as the composition is destroyed, wood flour particles swell in the formation water and get pinched at the sites of narrowing of pores and cracks, which ensures redistribution of filtration flows in the reservoir volume. On the other hand, the oil-soluble nonionic surfactant present in the composition promotes the coalescence of oil droplets in the reservoir in the form of a water-oil emulsion and the formation of an oil phase.

 This set of properties of the developed composition prevents both the complete precipitation of dispersed filler near the injection wellbore zone and the removal of filler to production wells, which effectively limits the flow of formation water and ultimately the displacement of oil from the reservoir.

 Salient features of the developed composition is the following.

 1. Use of a nonionic surfactant. Nonionic surfactant provides effective dispersion and retention of wood flour particles in the composition, prevents premature swelling of wood flour in water and allows you to adjust the viscosity properties of the composition as a whole.

 2. An additional introduction to the composition of wood flour (DM). Wood flour has a large dispersion in particle size (from 0.1 μm to 1 mm) and is capable of swelling in water. This provides the ability to influence the composition on pores and cracks of various sizes and to prevent the removal of particles of wood flour from the formation.

3. The use as a nonionic surfactant of an oil- or oil-soluble nonionic surfactant, for example, emulsion, neftenol, neonol AF _9-4 , AF _9-6 or OP-7. These nonionic surfactants are soluble in various petroleum products, allow you to prepare compositions with desired properties and contribute to the coalescence of residual oil in the reservoir.

4. The ratio of components in the composition, wt.%:
Wood flour - 0.1-5
Nonionic surfactants - 0.5 - 5
Oil product - 3 -10
Water - The rest.

 The specified ratio of the components provides the creation of a sedimentation-stable composition with high efficiency when injected into the oil reservoir in order to limit the influx of formation water.

 The composition is prepared as follows.

 For example, take 3 g of wood flour and place in a glass. Then pour 5 ml of oil containing 1 g of emulsion and mix. Next, the resulting mixture is poured into 91 ml of mineralized water and intensively mixed with a mechanical stirrer for 10-20 minutes. A homogeneous stable composition is obtained with the following content of components, wt.%: Wood flour 3; Nonionic surfactants 1; oil 5; water 91. In a similar manner, formulations with other nonionic surfactants and other component contents are prepared.

To prepare the composition, reagents and substances of domestic production are used: wood flour; oil, diesel fuel, gasoline; emultal, neftenol, neonol AF _9-4 , neonol AF _9-6 , neonol AF _9-9 , OP-4, OP-7.

 The effectiveness of the developed and known composition was determined in laboratory conditions by assessing their stability at temperature and studying in the process of oil displacement from a heterogeneous highly permeable reservoir model. The assessment was carried out by changing the filtration rates through the highly permeable and low permeability layers, by the increase in pressure in the system, as well as by the increase in oil displacement coefficients.

 Studies of oil-displacing properties and fluid filtration processes were carried out on a unit designed on the basis of a standard unit type UIPK. The installation simulates reservoir conditions and allows you to maintain the necessary pressure and temperature, as well as control the flow of water and oil, filtered through a reservoir model.

 Two steel columns 60 cm long and 3.7 cm in diameter, filled with disintegrated core and simulating interlayers of various permeabilities of the Samotlor field in Western Siberia, were used as a reservoir model. The permeability of the columns varied from 3080 to 33000 mD; the permeability ratio in the model was 5.3 - 7.4. Preparation of the reservoir model and the fluids for the experiments was carried out in accordance with STP 0148070-013-91 "Methodology for laboratory studies on the displacement of oil by reagents."

 Example 1. The study of the stability of the developed compounds.

The prepared compositions were placed in a thermostat with a temperature of 70 ^o C and kept for 24 hours. At the end, the stability of the compositions was visually assessed. The results are presented in table. 1.

 Example 2. Determining the effectiveness of the redistribution of filtration flows and oil displacement coefficient.

 The reservoir model is saturated with water with a total salinity of 18 g / l, and then with oil from the Samotlor field. Next, the columns are thermostated at reservoir temperature and oil is displaced by mineralized water to 100% watering of the recovered liquid. At the end, measure the ratio of the rates of fluid filtration through the interlayers, the pressure increase in the system and calculate the oil displacement coefficient. Then, the studied or known composition with a volume of 20% Vpore is pumped into the model. Next, mineralized water is pumped until the oil evolution ceases. Again measure the ratio of the rates of fluid filtration through the interlayers, the increase in pressure in the system and calculate the increase in the coefficient of oil displacement.

 The results of the experiments are presented in table. 2.

 Experiments 1 and 8 correspond to the transcendental ratios of the components in the proposed composition. Experiment 9 was conducted with the composition of the prototype.

 The results presented in example 1 show that the ratio of components proposed in the composition allows to obtain stable systems that do not emit both wood flour and oil product under the influence of temperature.

 Tests of the compositions for the redistribution of filtration flows in the reservoir models show their high efficiency exceeding the effectiveness of the composition of the prototype. At transcendental concentrations of the components (experiments 1 and 8), the compositions are ineffective. In one case, a substantial redistribution of filtration flows (change in filtration rates) is not achieved, in the other, a highly permeable interval is blocked and a sharp increase in pressure in the system occurs. The latter in relation to reservoir conditions means the shutdown of the water-washed interbed from the development and a significant decrease in the injectivity of the injection well.

 With the selected ratio of components (experiments 2-7) using the developed composition, a decrease in the filtration rates in the interlayers and a significant increase in the oil displacement coefficient are achieved. The use of the composition of the prototype in the conditions of the experiments is ineffective, due to the non-selective colmatation of both layers, accompanied by a sharp increase in pressure in the system and attenuation of fluid filtration.

 In practice, the composition is used as follows. According to the geological and physical studies, the degree of heterogeneity of the formation in the interval of perforation of the injection well is determined. Next, the volume of the injected composition, necessary for the mudding of the interval over which water breakthrough occurs, is estimated. Then, nonionic surfactants are added to the selected volume of oil product, mixed, and wood flour is also added with stirring. The resulting suspension using a pumping unit is dosed into the water stream in a certain ratio to obtain the stability of the composition. Then the rim of the composition is pressed into the reservoir with water and then pumped water is pumped.

 Thus, the use of the proposed structure allows you to effectively limit water inflow by partially plugging the water-washed intervals and fractures of the reservoir and connecting stagnant and slightly drained zones to the filtration process.

Claims (1)

1. The composition to limit the influx of formation water, including oil, surfactant and water, characterized in that the composition contains a nonionic surfactant (nonionic surfactant) and additionally wood flour in the following ratio, wt.%:
Oil product - 3 - 10
Nonionic surfactants - 0.5 - 5.0
Wood flour - 0.1 - 5.0
Water - Else
2. Composition according to claim 1, characterized in that the nonionic surfactant is used as the oil- or maslovodorastvorimoe nonionic surfactant, e.g. emultal, Neftenol, neonol AF _{9 - 6} or OP-7.

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