RU2097546C1 - Method of intensifying oil production - Google Patents

Abstract

FIELD: oil and gas production. SUBSTANCE: reagent, in particular, aqueous solution of multifunctional surfactant composition, is pumped in into borehole. Bottom zone is subjected to pulse treatment all over the depth of bed using electric discharges in reagent medium while continuously displacing electric- discharge machine in upward direction. Treatment consists in at least three identical successive cycles in on-off mode. Pulse frequency and velocity of discharge machine displacement are chosen in dependence on actual porosity of drilled bed and taking into consideration, preliminarily found on core material, empirical relationship between number of electric discharge pulses per 1 m of bed and mineral porosity. Pause time in each cycle is accepted to be at least 30 min. Such system treatment of bed allows considerably increasing depth of bed stimulation so restoring and, in some cases, improving collector property of bed. EFFECT: intensified oil production. 1 dwg

Description

 The invention relates to the oil and gas industry and can be used to increase oil recovery.

A known method of intensifying oil production, based on the impact on the bottom of the formation with an electro-hydraulic shock wave excited by a spark gap, and the subsequent selection of oil from the well [1]
The disadvantages of this method include the low efficiency of its use in conditions of high content of asphalt-resin-paraffin deposits of paraffin.

Closest to the claimed invention is a method that includes a pulsed treatment of the bottomhole zone of the well with electric discharges of an electric discharge device, carried out by at least three identical successively implemented cycles carried out in the exposure-exposure mode, the effect being carried out with a pulse frequency of 4-10 Hz for 5- 10 minutes, and the shutter speed is 5-15 minutes, at the end of the last processing cycle, oil is selected [2]
The disadvantages of this method include the shallow depth of coverage of the bottom-hole formation zone by the impact and, as a result, the short duration of the observed effect of the impact, which leads to productivity losses both put into operation after the repair of wells and wells that are in the process of long-term operation in conditions of high content of paraffin deposits .

 The objective of the invention was to develop a method of intensifying oil production, which allows for a long period of time to increase the productivity of wells introduced after repair into operation, as well as wells that are in the process of long-term operation in conditions of high content of paraffin deposits, by increasing the depth of coverage of the bottom-hole formation zone by and restoration of reservoir properties of the formation.

 The problem is solved in that in a method of intensifying oil production, including pulsed treatment of the bottom hole zone of the well with electric discharges of an electric discharge device, carried out by at least three identical successively implemented cycles carried out in the exposure-exposure mode, and subsequent selection of oil according to the invention previously on core material establish the empirical dependence of the number of pulses of electrical discharges in the cycle per meter of formation from the porosity of the rocks, pulse treatment of the bottom-hole zone of the well with electric discharges injects the reagent into the formations, pulse processing of the bottom-hole zone of the well with electric discharges is carried out over the entire interval of the formation in the reagent medium while continuously moving the electric-discharge device from the bottom up, while the frequency of the electric discharge pulses and the speed of the electric-discharge device are set based on real porosity of the reservoir, taking into account the previously obtained empirical dependence, and the exposure time each cycle is set at least 30 min.

 The method is implemented as follows.

Raise downhole equipment to the surface. Reagent is pumped through the tubing (tubing). As a reagent, a 0.3% aqueous solution of a multifunctional composition of surface-active substances (surfactants) of the ML type can be used at the rate of 1-2 m ^{3 of a} solution per 1 m of operating power.

 From the well filled with the specified solution, the tubing is removed. With a geophysical elevator, an electric-discharge device consisting of a capacitor discharge device with a spark gap is lowered to the level of the lower perforations on a cable-cable. An electric discharge device is included to create a shock wave in the fluid filling the well. In this case, the electric energy stored in the capacitor is released into the spark discharge channel formed between the electrodes located at the level of the perforations. In this discharge, powerful compression waves and acoustic fields are formed in the medium of a reagent-aqueous solution of a multifunctional composition of ML-type surfactants. Compression waves, repeatedly reflected and transformed into tensile stress waves, develop and form new fracture channels, which contribute to a more intensive movement of the surfactant composition solution from the well into these channels, providing its contact with sediment deposits, their effective washing and, consequently, increase bottom-hole coverage depths by combined exposure. An electrodischarge device, constantly turned on, is moved from bottom to top along the entire interval of the formation.

 The drawing shows the empirical dependence n = f (m), where n is the number of pulses of electrical discharges per 1 m of the formation in each cycle, m is the real porosity of the formation. The dependence n = f (m) was previously obtained experimentally from the results of tests on core material of wells in an operating field. Based on the real porosity of the reservoir under development, taking into account the empirical dependence n = f (m), the speed of the electric discharge device and the frequency of the pulses of the electric discharges are set. In this case, the condition for matching the exposure time of the reproduction time of the number of pulses of electric discharges per 1 m of the formation corresponding to the real porosity of this formation is taken as the basis.

 Thus, having established the frequency of pulses of electric discharges and the speed of movement of an electric-discharge device, a combined treatment of the formation in the reagent medium is carried out with at least three equally sequentially implemented cycles, each of which includes an exposure mode and an exposure in each cycle of at least 30 minutes.

 Compared with the known method [2], the proposed method for combined treatment of the bottomhole zone allows to increase the depth of impact due to the intense pulsed electric discharge treatment in the reagent medium, which contributes to the creation of new cracks and the development of microcracks and a significant depth of penetration of the reagent into the formation.

 When electric discharge impacts on the bottom-hole formation zone in a reagent medium, including multifunctional water-soluble surfactant compositions of the ML type, the following occurs: an increase in the permeability of the bottom-hole formation zone due to an increase in the system of cracks and channels; cleaning perforations from asphalt-resin-paraffin deposits, deposits of mineral salts and other solid sediments; providing a larger contact area of the reagent with crushed sediments and rock due to deeper penetration into the reservoir; the growth of the washing, and subsequently inhibitory ability of the reagent; ensuring synergies in the treatment of the bottomhole formation zone and a significant increase in its effectiveness.

 As shown by experimental studies of high-voltage electrical breakdown of a 0.3% aqueous solution of a multifunctional water-soluble composition of ML-type surfactants, in addition to increasing the activity of the latter, which is expressed in an increase in the efficiency of the washing ability by 11.3-1.7 times, an increase in the compression pulse amplitude occurs in it , which is 1.3 times higher than in an aqueous electrolyte solution, which indicates a positive mutual influence of the reagent and electric discharge.

 The method is implemented by an electric-discharge downhole device, characterized by the following technological parameters: voltage of the supply network, 220 V, current frequency of the network 50 Hz, power consumption 2.0 kW • h; dimensions of the ground part, mm: length 500, width 400, height 200; underground part, mm: diameter 102, length 5500; ground mass not more than 20 kg; underground part no more than 200 kg.

The method was tested in sandstones, siltstones and calcareous dolomites. The initial permeability of the rocks was not less than 0.1 • 10 ^-15 m ² , the pH of the medium is not limited.

Example 1. The flow rate of the well in the field "Polaznaneft" Perm region before the impact was 4.2 tons / day. Oil-saturated rocks are represented by quartz sandstones and siltstones. Sandstone permeability is 100 • 10 ^-14 m ² , porosity is 11% of sand-siltstone 75 • 10 ^-14 m ² and 7%, respectively, the temperature in the reservoir is 45 ^o C, the exposure interval is 1150-1200 m. In a well pre-filled with 0.3% - a solution of a multifunctional soluble surfactant composition (ML type reagent) on a geophysical cable lowered the electric discharge device to the bottom. Taking into account the dependence n = f (m), each meter of the formation was treated with 30 pulses with a frequency of 0.8 Hz at a stored energy of 1 kJ and a speed of movement of the electric-discharge device of 100 m / h. Then the exposure was stopped for 30 minutes. After this time, the exposure cycle was repeated 2 more times, with a 30-minute exposure after each cycle, which contributed to a deeper penetration of the aqueous solution of the composition into the reservoir. As a result, each meter of the reservoir was treated with 90 pulses.

 Next, the selection of oil from the well began. As a result of the combined electric discharge in the reagent medium, the production rate increased to 99.9 t / day with an initial well production rate of 68 t / day. The duration of the effect is 200 days.

Example 2. is similar to example 1 with the only difference that the reservoir was represented by siltstones with permeability of 70 • 10 ^-14 m ² and porosity of 5%. The well production rate before the impact was 0.9 t / day, the impact interval is 1200-1225 m. n = f (m) each meter of the reservoir is treated with 150 pulses in equal 3 cycles with a shutter speed of 40 min. The speed of the electric discharge device is 50 m / h, the pulse frequency is 0.6 Hz. The oil production rate after exposure to 87.3 tons / day with an initial well production rate of 58 tons / day. The duration of the effect is 210 days.

 After the electric discharge effect described in the known method [2], the well production rate in most cases approached the initial one and only in some cases increased by 10-25%, while the duration of the effect did not exceed 100 days.

 The advantage of the proposed technical solution in comparison with the prototype is a stable increase in the flow rate of the wells after combined exposure by 30-45% of the initial one, while the duration of the operation of the wells with the resulting productivity increases by more than two times.

 Thus, the combined electric discharge effect in the reagent medium allows not only to restore, but also to improve the reservoir properties of the formation during the long-term operation of the well, to intensify oil production.

Claims (1)

 A method of intensifying oil production, including pulsed processing of the bottomhole zone of the well by electric discharges of an electric discharge device, carried out by at least three identical successively implemented cycles carried out in the exposure mode, followed by oil sampling, characterized in that an empirical dependence of the number of pulses is established on the core material electrical discharges in a cycle per meter of formation from porosity of rocks, before pulsed processing of bottom-hole Wells with electric discharges pump the reagent into the formation, pulse treatment of the bottomhole zone of the well with electric discharges is carried out over the entire interval of the formation in the reagent medium while continuously moving the electric discharge device from the bottom up, while the frequency of the electric discharge pulses and the speed of the electric discharge device are set based on the actual porosity of the formation taking into account the previously obtained empirical dependence, and the exposure time in each cycle is set to at least 30 min