RU2101486C1 - Method for isolation of brine water inflow - Google Patents

Abstract

FIELD: oil production industry. SUBSTANCE: according to method, improved efficiency of isolation of water-washed intervals of bed is achieved due to formation of stable insoluble sediment created in result of interacting solution of polybasic acid emulgated by means of oil-soluble surface-active matter in hydrocarbon liquid and compound containing salt of alkali-earth metal and representing water solution of salt and its emulsion in hydrocarbon liquid. Used as salt of polybasic acid are water-soluble silicates, phosphates or carbonates, and used as salt of alkali-earth metal are water-soluble salts of magnesium, calcium or barium. Method is realized by successive injection into well of emulsion containing salt of polybasic acid and compound containing salt of alkali-earth metal. Then, technological delay is undertaken for 12-36 h for reaction process and after that, well is brought into operation. EFFECT: high efficiency. 2 cl, 2 tbl

Description

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

A known method of isolating the influx of formation water, including the injection into the well of a hydrophobic emulsion and the subsequent injection of gas condensate [1]
As a result of such an impact on the formation, a hydrophobic emulsion with improved structural and mechanical properties is formed, which prevents the influx of formation water.

 The disadvantage of this method is the low efficiency when used on highly permeable and fractured reservoirs.

The closest technical solution, taken as a prototype, is a method that includes injecting into the formation a reverse emulsion obtained by separate emulsification of solutions of sodium sulfate and calcium chloride in a hydrocarbon liquid [2]
In reservoir conditions, after the destruction of the emulsion due to dilution with water, a precipitate of calcium sulfate forms, which helps to reduce the permeability of the water-saturated part of the collector.

 The main disadvantage of this method is its low efficiency when used on highly permeable and fractured reservoirs, due to the small depth of penetration of the emulsion into the reservoir and the partial solubility of the formed sediment. In addition, the method does not provide selective effects on the reservoir.

 The objective of the invention is the creation in water-saturated pores and fractures of the formation resistant to the action of reservoir fluids sediment, which effectively limits and isolates the influx of formation water.

 The problem is solved by sequentially injecting sediment-forming compositions into the formation: a reverse emulsion containing an aqueous solution of a salt of a polybasic acid, and a reverse emulsion or solution containing a salt of an alkaline earth metal. In this case, water-soluble silicates, phosphates or carbonates are used as a salt of a polybasic acid, and water-soluble salts of calcium, magnesium or barium are used as a salt of an alkaline earth metal.

 The essence of the developed technical solution is as follows. Using a water-soluble salt of polybasic acid, an inverse emulsion is prepared, which is then pumped into the well. Under reservoir conditions, the emulsion begins to decompose with the release of the aqueous phase, which leads to a partial precipitation due to the reaction of the salt of polybasic acid with mineralized water. However, the bulk of the salt does not react and penetrates deep into the water-saturated intervals of the reservoir.

 Subsequently, as a result of the injection of a composition containing an alkaline earth metal salt, and the diffusion of calcium and magnesium ions from the formation water, the process of sedimentation intensifies and occurs throughout the volume covered by the action.

 In the framework of the developed method, water-soluble silicates, phosphates or carbonates are used as the salt of the polybasic acid. When these salts interact with saline water and an alkaline earth metal salt, silicic acid gel, silicates, phosphates or alkaline earth metal carbonates are formed. These substances are practically insoluble in water, which ensures a longer duration of their insulating effect.

 Salient features of the developed technical solutions are.

 1. Sedimentary compositions: a solution of a salt of a polybasic acid emulsified in a hydrocarbon liquid and a composition containing alkaline earth metals are pumped separately. In this case, a solution of a salt of a polybasic acid emulsified in a hydrocarbon liquid is initially pumped into the formation. This ensures that the precipitating reagent salt of the polybasic acid penetrates deep into the formation and prevents the formation of sediment in oil-saturated intervals.

 2. An aqueous solution of an alkaline earth metal salt or an emulsion in a hydrocarbon liquid is used as a composition containing an alkaline earth metal salt. This allows, by varying the density of the composition and its compatibility with the first of the injected compositions, to widely control the rate of sedimentation in a certain interval of the formation and create conditions for its formation.

 3. As the salt of the polybasic acid, for example, water-soluble silicates, phosphates and carbonates are used. In the interaction of these salts with salts of alkaline earth metals, compounds insoluble in fresh and mineralized water are formed, which ensures a longer duration of their insulating effect. It is also possible to use water-soluble salts of other polybasic acids, forming insoluble compounds with salts of individual alkaline earth metals, for example, calcium oxalate, barium sulfate.

 4. As the alkaline earth metal salt, water-soluble salts of calcium, magnesium or barium are used. The use of salts of these metals allows to ensure the completeness of sedimentation and to regulate its distribution in the volume of the reservoir.

 The method is implemented as follows.

 Based on the geological and physical characteristics of the formation and current development indicators, a calculated volume of the inverse emulsion containing a solution of a polybasic acid salt and a composition containing an alkaline earth metal salt are prepared at a well planned for insulation work. The procedure for preparing the emulsion involves mixing certain volumes of a solution of a salt of a polybasic acid, a hydrocarbon liquid and an emulsion stabilizer of a poorly soluble surfactant. Mixing is carried out until a mixture is uniform in composition. A composition containing an alkaline earth metal salt is prepared by dissolving the salt in water or emulsifying the resulting solution in a hydrocarbon liquid. Next, reverse emulsion is injected into the formation, then a composition containing an alkaline earth metal salt is injected. The well is left to respond for 12-36 hours, and then proceed to its base.

To implement the method, the following reagents and commercial products containing them are used:
salts of polybasic acids: sodium silicate, sodium silicate solution (water glass), sodium phosphate, diammonium phosphate, calcium dihydrogen phosphate, sodium carbonate, etc.

 alkaline earth metal salts: calcium chloride, calcium nitrate, magnesium chloride, barium chloride, etc.

oil-soluble surfactants: emultal, petrochemical, neftenol, neonol AF _9-4 , AF _9-6 , OP-4, sodium salts of FFA, etc.

 hydrocarbon liquids: oil, diesel fuel, kerosene.

 For the preparation of aqueous solutions using industrial or commercial water.

 The use of the developed method for isolating the influx of formation salts of these salts of polybasic acids and salts of alkaline earth metals makes it possible to obtain stable precipitates that are practically insoluble in water and provide a longer duration of the technological effect.

In the table. 1 presents the values of the solubility product (PR) for a number of precipitates formed in accordance with the new method, and the precipitate obtained using the prototype method [3]
The effectiveness of the developed and known method was determined in laboratory conditions by studying the processes of oil displacement from a heterogeneous highly permeable reservoir model. Evaluation of the effectiveness of the methods was carried out by changing the filtration rates through a highly permeable water-washed layer, as well as by changing the proportion of oil in the fluid extracted from the reservoir model as a whole.

 Studies of the insulating effect of the methods and processes of liquid filtration were carried out on the installation, designed on the basis of a standard installation type UIPK. The installation allows you to maintain the necessary pressure and temperature, as well as to control the flow of water and oil, filtered through the 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 column permeability varied from 1570 to 40700 mD, the permeability ratio in the model was 10.2-19 , 7, which suggests the presence of cracks in the reservoir.

 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. Determining the effectiveness of insulation of a water-washed interbed of a heterogeneous reservoir model and the water content of the recovered fluid.

 The heterogeneous reservoir model is saturated with water with a total mineralization of 18 g / l, and then with oil from the Samotlor field. Next, the columns are thermostated at reservoir temperature and oil is displaced to 100% water cut of the liquid extracted from the highly permeable interlayer. At the end, the water filtration rate is measured for a high-permeability interlayer, the rate of water and oil filtration for a low-permeable interlayer, and the water content of the recovered liquid is calculated for a single period of time. Then, a solution of a salt of a polybasic acid with a volume of 15% V pores and an aqueous solution of an alkaline earth metal or its emulsion in a hydrocarbon liquid with a volume of 15% V pores are sequentially pumped into a reservoir model. The compositions are pushed into the reservoir model, after which the fluid injection is stopped and the model is left to react for 24 hours. Next, the mineralized water injection is resumed and, after stabilization of the filtered fluids, appropriate measurements are made.

 Reactive test compositions are prepared as follows. For example, 10 g of sodium silicate is dissolved in 40 ml of water, then, using a mechanical stirrer, the resulting solution is emulsified in 53 ml of oil containing an additional 2.5 g of an oil-soluble surfactant, for example, emulsifier. After mixing, a homogeneous mobile emulsion containing 10% sodium silicate is obtained.

 A composition containing an alkaline earth metal salt is prepared by dissolving, for example, 10 g of calcium chloride in 90 ml of water or dissolving 10 g of salt in 40 ml of water and then emulsifying the solution in 53 ml of oil using an oil-soluble surfactant. In both cases, formulations containing 10% calcium chloride are obtained.

 The test results of some variants of the developed method are presented in table. 2.

 It is shown that the new method provides a significantly more effective reduction in the rate of water filtration through a highly permeable interlayer compared with the prototype method.

 In some cases, the filtration of water through a high-permeability interlayer practically ceases, and the water cut value is determined by the ratio of oil and water filtered through a low-permeable interlayer.

 Carrying out insulation work in accordance with the developed method allows avoiding the mudding of oil-saturated intervals of the reservoir due to the separate injection of sediment-forming compositions and the possibility of using an aqueous salt solution as a composition containing an alkaline earth metal salt. The latter guarantees the formation of sediment in the lower most washed-out part of the formation, which is most significant during breakthroughs of bottom water or low formation thickness.

 The prototype method does not have the indicated selectivity of action, and its use leads to colmatization of oil-saturated intervals.

 In practice, the developed method is implemented as follows. According to geological and physical studies, the degree of heterogeneity of the formation and its nature in the interval of perforation of the well are determined. Next, the volumes of sediment-forming compounds are calculated to ensure effective isolation of the interval over which water breakthrough occurs. Then, sediment-forming compositions are prepared: first, by dissolving the polybasic acid salt in water and then emulsifying the solution in a hydrocarbon liquid containing an oil-soluble surfactant; the second by dissolving the alkaline earth metal salt in water or by dissolving the salt in water and emulsifying in a hydrocarbon liquid containing an oil-soluble surfactant. Emulsification of aqueous solutions in a hydrocarbon liquid is carried out using pumping units or special mixers. Next, the prepared sediment-forming compositions are sequentially pumped into the reservoir and pushed with a buffer of water into the reservoir. The liquid injection is stopped, the well is left to respond for 12-36 hours. When using the method on injection wells, the response time can be reduced, after that, oil production is induced in production wells, and water injection is started in injection wells.

Claims (3)

 1. A method of isolating the influx of formation water, comprising injecting a solution of a polybasic acid salt emulsified in a hydrocarbon liquid using an oil-soluble surfactant and a composition containing an alkaline earth metal salt, characterized in that the solution of a polybasic acid salt emulsified in a hydrocarbon liquid is initially pumped, and as a composition containing an alkaline earth metal salt, an aqueous solution of an alkaline earth metal salt or an emulsion thereof in a hydrocarbon liquid is used.  2. The method according to claim 1, characterized in that, for example, sodium silicate, sodium phosphate or sodium carbonate is used as the polybasic acid salt.  3. The method according to claim 1, characterized in that as the alkaline earth metal salt, for example, calcium chloride, magnesium chloride or barium chloride is used.

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