RU2085721C1 - Method for treating down-hole zone of bed - Google Patents

Abstract

FIELD: oil production industry. SUBSTANCE: this can be used in intensifying oil production and increasing oil output in difficult conditions of developing deposits and particularly in treating down-hole zones of vertical, incline and incline-horizontal wells and also wells with second hole. According to method, elastic vibrations are applied to create channels or fissures in down-hole zone. Determined are depths, opening and number of created or existing fissures or channels in down-hole zone having hydraulic connection with well. Well liquid is investigated and its density and compressibility are determined. Elastic vibrations are applied in interval of perforations at resonance frequency calculated according to summary of aforesaid parameters depending on packer location depth, well diameter and its depth. Application of this method increases depth of wave penetration into oil bed being treated due to extended effective radius of source. Efficiency of treatment is enhanced due to improved spacious and power distribution of elastic vibration field in oil bed and also due to improved vibration characteristics of down-hole zone connected with new character of radiation of vibration energy that is creation of resonance intensive pulsing of flow rate in passages or fissures. EFFECT: high efficiency.

Description

 The invention relates to the oil industry and can be used to intensify oil production and increase oil recovery in difficult conditions of field development, in particular, in the processing of the borehole zone of a formation of vertical, deviated, deviated horizontal wells, as well as wells with a second wellbore.

 Known methods of intensifying oil production by wave action of elastic vibrations on the borehole formation zone (US patent, N 2437456, CL 166-90, publ. 1948, US patent, N 4164978, CL, 166-294, publ. 1978).

 A disadvantage of the known technical solutions is their low efficiency of wave action.

 The closest technical solution is a method of developing an oil deposit, including the creation of cracks in the reservoir and the wave action by elastic vibrations, (Gadiev S. M. Use of vibration in oil production, M. Nedra, 1977).

 A disadvantage of the known technical solution is the low transmission efficiency of elastic vibrations in the formation due to inconsistencies in the frequency of oscillations generated by the source in the well with the frequency of hydraulic vibrations in the reservoir-crack system.

 The purpose of the technical solution is to increase the efficiency of the method by increasing the depth of the resonant penetration of waves into the treated formation by increasing the effective radius of the source.

 The goal is achieved in that in the known method, including the creation of cracks in the formation and subsequent exposure to elastic vibrations, determine the depth and opening of natural and / or specially created by the fracture of the formation of cracks or channels, their number in the perforation interval, conduct research on the properties of the well fluid, determine it density, compressibility, place a generator of elastic vibrations in the perforation interval, and the vibrations are carried out with a resonant frequency calculated from the totality of certain pairs ters depending on the borehole diameter, depth, depth of the packer unit.

 The processing efficiency increases both due to an improvement in the spatial-energy distribution of the field of elastic vibrations in the formation, and due to an improvement in the filtration characteristics of the bottom-hole zone, associated with the new nature of the emission of vibrational energy by the appearance of resonant intense flow pulsations in channels or cracks.

 The method is carried out in the following sequence.

 The producing or injection well selected for processing according to the proposed method is washed with patterning, then in the perforation interval in accordance with the selected method of creating channels or cracks in the bottomhole zone, the bottomhole device is lowered and the formation is fractured. According to previously collected data on the elastic-mechanical and other properties of the reservoir, and the borehole fluid, the parameters of the formed cracks are estimated. Based on the totality of certain parameters of the bottom-hole zone, the borehole fluid and the characteristics of the well, the resonant frequency of the excitation of oscillations at the bottom of the well is calculated.

 The generator is lowered on the string of tubing to the required depth and begin to treat the well with elastic vibrations. The duration of treatment for a particular type of formation is determined by the results of preliminary experiments.

 The method can be carried out without preliminary fracturing or without the preliminary formation of special channels in the bottomhole zone. Then, when calculating the resonant frequency, the known data on the values of the parameters of the natural fractures of the PSZP collector are used, or the characteristics of the existing perforation channels of the well are used.

 The impact on the PSZP of elastic vibrations, the frequency of which is determined by the parameters of pre-made or natural channels or cracks that have a hydraulic connection with the well, as well as the properties of the well fluid and the characteristics of the well, can significantly improve the filtration properties of the PSZP, align the inflow profile or the injectivity profile along the perforation interval, include inoperative interlayers.

 The method relates to the category of environmentally friendly activities.

 An example of the method at the Urshak field of the Republic of Bashkortostan.

где
E₁, E₂ модули Юнга до и после воздействия, МПа;
g_∞ боковое горное давление, МПа;
P давление, создаваемое МГДБК, МПа;
Суммарное поперечное сечение (раскрытие) определяют по формуле:

где
N плотность перфорации, отв/м;
δ диаметр перфорированного отверстия, м;
h значение перфорированной толщины пласта, м;
Коэффициент сжимаемости воды примем равным 0,45 1/ГПа. Модуль Юнга породы составляет 40,0 ГПа. В большинстве случаев после воздействия ПГДБК модуль Юнга возрастает в два раза. Боковое давление принимается равным 184 МПа. Скважина имеет глубину 2330 м, интервал перфорации 2320-2325 м. Глубина установки пакера 2320 м. Плотность перфорации составляет 18 отв./м. Диаметр перфорационных отверстий по результатам фотографирования 0,005 м. Диаметр эксплуатационной колонны 0,13 м. Приемистость скважины не более 5 м³/сут.The injection well selected for processing was drilled into the Biysk horizon with the following characteristics:
Reservoir pressure 20.0 MPa,
Reservoir permeability 57 milli Darcy,
Porosity 12%
Formation thickness 5.0 m,
The density of produced water 1159 kg / m ³
After flushing and templating, a downhole device, for example, a powder-free pressure generator without housing pressure (ПГДБК-100), is lowered into the perforation interval. The cable is removed, the pressure value is determined and the parameters of the formed cracks are evaluated. Based on the assumption that the main part of the pulse energy generated during the combustion of PHDBK is spent on creating one vertical crack, it is possible to determine the length of the crack using the modified Zheltov formula Yu.P. (Reference guide for the design of the development and operation of oil fields. Oil production / Ed. Sh.K. Gimatudinova. M. Nedra). Moreover, if the length of the initially formed crack in most cases is 10 m (experimental data), then the length of the residual crack will be determined by the formula:

Where
E ₁ , E ₂ Young's modules before and after exposure, MPa;
g _∞ lateral rock pressure, MPa;
P pressure created by MGDBK, MPa;
The total cross section (disclosure) is determined by the formula:

Where
N perforation density, holes / m;
δ diameter of the perforated hole, m;
h is the value of the perforated formation thickness, m;
The compressibility coefficient of water is assumed to be 0.45 1 / GPa. Young's modulus of the rock is 40.0 GPa. In most cases, after exposure to PHDBK, Young's modulus doubles. Lateral pressure is taken equal to 184 MPa. The well has a depth of 2330 m, the perforation interval is 2320-2325 m. The depth of the packer is 2320 m. The perforation density is 18 holes / m. The diameter of the perforations according to the results of photographing is 0.005 m. The diameter of the production casing is 0.13 m. The injectivity of the well is not more than 5 m ³ / day.

As a result of combustion, a pressure of 47.0 MPa was reached in the borehole perforation interval of the powder pressure generator in the borehole. As a result, a continuous radial crack with a length of 3.12 m and an opening of 0.00058 m ² formed in the PSZP.

 The resonant frequency of excitation of oscillations at the bottom of the well, determined taking into account the obtained parameters, was 8.5 Hz.

As a generator of elastic vibrations, a hydraulic borehole generator of the ARMS-MEDIT design is used, which allows generating high-amplitude pressure fluctuations in the range of 1-200 Hz, with frequency adjustment and precise presetting to a given frequency, with a working fluid flow rate of 3-5 dm ³ / s .

 The generator is attached to the tail of the tubing string.

 At a distance of 3.0 m and above the vibrator, a PD-G type packer is installed. The generator is lowered on the tubing string to a depth of 2323 m. The operation of installing the packer in the well is performed. Establish wellhead fittings, type ANL, and tie it to a pump unit of type CA-320. The unit is turned on, and with pumping the liquid (produced water) through the tubing through the generator, they are subjected to elastic vibrations for 2 hours with a frequency of 8-10 Hz.

A week after the end of vibration exposure and the extraction of underground equipment (generator) and the launch of the well for injection, its injectivity was measured and the injectivity profile was evaluated. The injectivity of the base was 120 m ³ / day at a discharge pressure of 13.0 MPa.

Claims (1)

 A method of processing the near-wellbore zone of a formation, including the action of elastic vibrations and the creation of channels or cracks, characterized in that before the wave action, the depth, opening and number of previously created or already existing in the bottom-hole zone of cracks or channels having a hydraulic connection with the well are determined, the properties are studied downhole fluid, determine its density and compressibility, and the impact of elastic vibrations is carried out in the perforation interval with a resonant frequency, calculated of the above-defined set of parameters depending on the diameter of the well, the depth and the packer setting depth.