RU2105135C1 - Method for additional development of oil deposit - Google Patents

Abstract

FIELD: oil and gas production industry. SUBSTANCE: this relates to increasing final oil recovery from bed by accelerated reformation of fully watered oil deposit. According to method, this is achieved by creating vibro-resilient oscillations in oil bed by means of subsurface vibration sources located in existing and additionally drilled multihole wells and displaced up and down of bore-holes. EFFECT: higher efficiency. 2 dwg

Description

 The invention relates to the oil industry, in particular to methods for developing oil fields, and can be used to increase the final oil recovery.

 A known method of developing a waterlogged oil reservoir, which consists in the application of vibroseismic effects on the reservoir. The essence of the process according to the known method consists in exposing the reservoir to elastic vibrations created by moving and downhole vibration sources moving on the earth's surface.

However, the known method has the following disadvantages:
- the efficiency of surface sources of vibroelastic vibrations is low due to large losses of vibrational energy in the rock mass, separating productive formations from the earth's surface and in the thousands of meters;
- the impact radius of the borehole vibration sources is insufficient for the practical coverage of the radius of the oil well’s supply with a modern grid for drilling holes.

 The aim of the invention is to accelerate the reformation of a completely flooded oil reservoir and increase its final oil recovery.

 This goal is achieved by the fact that vibroelastic vibrations are created in the reservoir using well vibro sources located in existing and additionally drilled directional multilateral wells and moved down the wellbore.

 It is known that upon termination of the development of completely flooded oil deposits in the reservoir, an extremely slow gravitational separation of oil and water will occur. At the same time, oil, as lighter, will accumulate in the upper part of the reservoir.

 The duration of this process can last for many years.

 However, the oil filtration rate can be accelerated in various ways, in particular by vibro-seismic effects on the formation.

Under the influence of elastic vibrations, the structure of visco-plastic and viscoelastic fluids that acquire the properties of Newtonian fluids is destroyed. In addition, when the pressure amplitude is reached above the shear stress, the structures of the surface liquid layer begin to collapse near the walls of the pore channels. Consequently, a combination of several factors favoring the filtering process appears:
- the appearance of the Newtonian character of the fluid flow;
- decrease in oil viscosity;
- an increase in the effective cross section of pores.

 In addition, the interfacial tension at the water-oil interface decreases.

 In a water-flooded oil reservoir in the presence of a free gas phase, the process of gravitational separation of liquids (oil, water) during vibration exposure can be accelerated for another reason. Gas bubbles are always firmly bound to oil droplets. When an acoustic field appears, acoustic forces begin to act on gas bubbles, contributing to their emergence. Therefore, oil droplets associated with gas bubbles are affected by additional lifting force.

 The use of multilateral wells allows to increase the radius of action of borehole vibration sources, which can be used for well-known downhole vibrators: hydraulic, mechanical, etc.

 The presence of all the factors discussed above significantly accelerates the processes of gravitational separation (segregation) of oil and water and the artificial reformation of waterlogged oil deposits.

 The method is as follows (see Fig. 1, 2).

 In the area of reservoir 1, where it is planned to conduct vibrational impact on productive completely irrigated formations 2, additionally directional multilateral wells 3 are drilled, located in the center of the cells of the drilling network of this reservoir. All wells 3, 4 of section 1 are equipped with downhole vibration sources. At the same time, vibration exposure begins on the near-wellbore areas of the reservoir, from bottom to top in its thickness.

 The duration of exposure is determined by calculation, taking into account the thickness of the reservoir, the power of the vibration source, the viscosity of the reservoir fluid, oil saturation, physical parameters of the reservoir. Then the process of vibration exposure is suspended for a period equal to the time of exposure to the formation, after which the development of the reservoir resumes.

Claims (1)

 A method of additional development of a completely flooded oil reservoir using a vibroseismic effect on a reservoir, characterized in that the vibroelastic vibrations in the reservoir are created by vibration sources located in existing and additionally drilled multilateral wells and moved down the wellbore.

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