RU2103489C1 - Method for development of watered oil deposit - Google Patents

Abstract

FIELD: oil production industry. SUBSTANCE: this is aimed at increasing oil output due to enlarged embracing of bed by watering and reducing permeability of water-passing passages. According to method, initially injected into injection wells is sediment producing reagent which is waste of petrochemical production process containing 10-15% of sodium hydrate in mass. Injection is effected with use of 8-12 g of reagent per 1 m of bed thickness in one injection well. Then, injection wells are started for operation. After some period (1-2 months) nearest producing wells will react to aforesaid action by reduced watering of recovered liquid. Water is injected into injection wells until watering of recovered liquid reaches value existed in nearest producing wells prior to aforesaid treatment. Then, sediment producing reagent is again injected into same injection wells. EFFECT: high efficiency.

Description

 The invention relates to the oil industry, in particular to methods for developing oil fields.

 There is a method of developing a waterlogged oil reservoir, which consists in injecting an alkali solution into the formation in order to increase the final oil recovery coefficient [1].

 The disadvantage of this method is the need to use expensive equipment and a reagent for organizing alkaline flooding.

 Closest to the invention in technical essence and the achieved effect is a method of developing a waterlogged deposit, which consists in organizing in-situ sedimentation, carried out by the interaction of alkali rims with a solution of metal salts [2].

 The disadvantage of this method is the need to create large in volume rims of expensive reagents.

 The purpose of the invention is to increase the efficiency of the method by increasing the coverage of the formation by water flooding and reducing the permeability of water channels.

 The goal is achieved by the fact that in the known method of developing an irrigated oil reservoir, including the selection of liquid from production wells, the organization of in-situ sedimentation by injection of an alkali-based reagent into injection wells, the sediment-forming reagent is first injected into injection wells and put into operation, water is injected until the average water cut of the products of the nearest producing wells after a period of its decrease and increase reaches the value that existed before the treatment otok injection wells, then again carried download sediment-reactant into the same injection wells, as a rain-reagent use waste material containing 10 - 15% sodium hydroxide solution, and the consumption of reagent is 8 - 12 tons per 1 m layer thickness in an injection well.

 The method is as follows.

 Sediment-forming reagent is pumped into injection wells, which is a waste product and contains 10-15% sodium hydroxide by weight. The injection is based on the consumption of 8 - 12 tons of reagent per 1 m of formation thickness in 1 injection well.

 At the same time, injection wells are put into operation and water is pumped until the average water cut of the products of the nearest producing wells after a period of time of reduction and increase in water cut reaches the value that existed before the treatment of injection wells.

 After that, the sediment-forming reagent is again pumped into the same injection wells.

 The reagent containing alkali injected into the formation interacts with divalent metal ions in mineralized water, resulting in a gel-like precipitate.

 This will lead to a decrease in the conductivity of water channels and an increase in coverage by low permeability interlayers. As a result, the water cut of the nearest producing wells is reduced, and then gradually it begins to increase and finally reaches the value that existed before the treatment. The latter signals the need to re-inject the reagent into the reservoir.

This development method was tested on a deposit site having the following development parameters and indicators:
Oil saturated thickness - 7.1 m
Porosity - 18%
Permeability - 0.247 μm ²
Oil viscosity in reservoir conditions - 2.8 MPa. with
Reservoir pressure:
Initial - 27.1 MPa
Current - 25.3 MPa
Average water cut - 84%
Well stock:
Mining - 4 units.

 Injection - 1 unit.

 First, 74 tons of production waste containing 12% sodium hydroxide by weight were pumped into the injection well. After that, this well was connected to the water conduit of the water flooding system. After a period of 1 month, there was a decrease in water cut in the closest producing wells. The average water cut decreased from 84 to 78%. Over the next 6 months, this indicator gradually decreased to 71%, after which it began to increase over the course of 4 months and reached 84% (which existed before the injection well was processed). Then, the reagent was injected in the same amount into the injection well.

 The effectiveness of the proposed method amounted to 15.7% of the total annual oil production of the site deposits.

 Comparison of the injection profiles taken before and after this technology in the injection well showed that new interlayers were involved in the development process.

Sources of information
1. Surguchev M. L. Secondary and tertiary methods of increasing oil recovery. M .: Nedra, 1975.

 2. Gorbunov A.T. and Buchenkov L.N. alkaline water flooding. M .: Nedra, p. 52 - 53.

Claims (1)

 A method of developing a water-cut oil reservoir, including the selection of liquid from production wells, the organization of in-situ sedimentation by injection of an alkali-based reagent into injection wells, characterized in that the sediment-forming reagent is first injected into injection wells and the injection wells are put into operation, water is pumped before until the average water cut of the product of the nearest producing wells after a period of its decrease and increase reaches the value that existed before treatment of injection wells, after which the sediment-forming reagent is again injected into the same injection wells, while the total consumption of sediment-forming reagent is 8 12 tons per 1 m of formation thickness in the injection well.