RU2066746C1 - Method for recovery of dry oil and gas wells - Google Patents

Abstract

FIELD: and gas production; applicable in increased oil recovery from formation with the use of migration geoeffect and cavitation. SUBSTANCE: used as vibration source is external surface of casing string to which layer of rare-earth element is applied. Electrodes are installed into the layer and connected to the source of exciting voltage, and powerful vibrations are excited in the selected range in combination with injection into the formation of loosening solution heated up to 180 C. Then, pulse hydraulic fracture is made and cavitation phenomena are initiated in the formation to increase formation permeability and oil recovery. Working fluid is used in form of heated solution of sodium hydroxide or sodium hydroxide with methane and 3-5% surfactant. EFFECT: higher oil recovery from formation. 6 cl, 1 dwg

Description

 The claimed invention relates to the field of oil and gas production and can be used for resuscitation of dry oil and gas wells using an elastic migration geo-effect and cavitation.

A known method of resuscitation of dry oil and gas wells by drilling additional shafts [1]
The known method is time-consuming, low-tech, does not use advanced technology to increase oil recovery to increase the permeability of the reservoir.

The closest in technical essence is the method of resuscitation of dry oil and gas wells, including drilling a well, lowering the casing into it, placing vibration sources of vibration at a depth of the formation, determining the direction of the main stresses in the rock mass and then creating cracks oriented in the direction of action of the minimum main voltage by pumping the working fluid into the well in a pulsating mode in combination with vibration [2]
The known method is also time-consuming, non-technological, due to the difficulty of placing air sources at significant depths due to a decrease in the diameter of the well and suspension of sources on the cable, it does not use an elastic migration geo-effect and does not take into account the structural features of the formation, the method does not allow working in the selected frequency range of the resonant reservoir mode.

 This goal is achieved by the fact that according to the method, before the casing string is launched, a layer of a substance consisting of a rare-earth element with the addition of 5-10% binder and built-in electrodes is applied to it, the electrodes are connected to a voltage source to generate elastic vibrations, elastic vibrations are recorded by seismic equipment, they are specified the location of the field, set in the range of exposure to the packers with an interval of 2 to 30 m, perforate the casing between the packers and carry out phased vibration in at the beginning in the frequency range of the transitional regime, and then with a frequency equal to the frequency of the rock mass, the stress-strain state of the rocks in the mass is measured and the pressure amplitude in the alternating elastic wave is determined, and then vibrations are carried out with a pressure amplitude equal to 0.5 of the breaking stresses in the course of time at which compression deformations pass into tensile deformations, then they act at a frequency equal to the frequency of injection of the working fluid into the well until hydraulic fracturing is achieved, while as a working fluid, a solution of sodium hydroxide or sodium hydroxide with methanol and a 3-5% surfactant surfactant is used.

Vibration during the transition mode is carried out in the frequency range 600-1500 Hz, and as a working fluid use a solution heated to 180 ^o C.

Vibration in the transition mode is carried out in the range of 1-2 kHz by a laser beam supplied from the surface of the well through the fiber, and a solution heated to 60-80 ^o C is used as the working fluid, and cavitating phenomena are initiated in the rock mass.

 Before hydraulic fracturing, cement slurry is supplied to the base of the well, and vibration exposure is carried out sectionwise during the process of pumping cement into the annulus and with the beginning of the process into the base of the well, and vibration exposure is carried out for a time at which the strength of the cement stone reaches half the strength of their standard value.

0.6% of caustic soda and 1.2-1.8% of proppants with a particle size of 0.03-0.6 mm and a density of 3.2-6.3 g / cm ³ are added to the working fluid.

 After hydraulic fracturing, fastening solutions are injected into the formed cracks and technogenic voids.

 The drawing shows a diagram of the implementation of the method, where 1 thickness of rocks, 2 layer, 3 well, 4 casing, 5 layer of rare-earth element deposited on the surface of the casing, 6 annular space filled with rare earth with the addition of 5-10% binder, 7 pulse voltage source, 8 pump laser, 9 optical fiber, 10 - packer, 11 fluid between packers, 12 holes made in the casing.

The method is as follows: before lowering the casing string on the outer surface of the casing put a layer of rare earth element type RFe ₂ ; SmFe ₂ , TbFe ₂ ; DuFe ₂ ; HoFe ₂ ; EGFe ₂ ; TmFe ₂ ^ possessing gigantic magnetostriction when applying a pulsed exciting voltage from 380 to 600 V, and up to 50% of electromagnetic energy passes into the energy of elastic vibrations in a wide frequency range from 60 to 6000 Hz with a rare earth thickness of 2-5 cm with the addition of a binder 5-10% as which use fine-grained cement. The layer of the rare-earth element is applied to the casing 4 sections vb of 4-6 m in increments of 12-15 m, the excitation voltage 7 is applied through the electrodes to the layer and, by changing the frequency and magnitude of the excitation voltage, the parameters of the elastic waves generated in formation 2 and containing rocks are controlled 1, then fastening solutions are injected into the annulus 6, which are pressed through, starting from the base (bottom) of the well in combination with vibration, and the vibration is carried out with an amplitude of pressure in an alternating wave of not more than 0, 5 the values of destructive stresses for the rocks composing the walls of the well 3, during the time at which the strength of the cement stone reaches half of their strength from their standard value.

After that, elastic vibrations in the transient mode of 60-1500 Hz are excited, elastic vibrations are recorded by seismic equipment, the received seismic information is processed and analyzed, the location of the oil or gas field is determined, the space of the well 3 is limited by the depth of the reservoir with packers 10, and the space is filled with a temperature from 60 to 80 ^o C, the casing 12 between the packers and perforate through the fiber from the pump laser 8 is injected into the formation in the elastic energy accumulation mode and excite in a mountain range, and n aste powerful vibratory oscillations, previously bringing massif 1 into oscillation at frequencies from 60 Hz to 1000 Hz in conjunction with the injection into it of softening solutions, which is used as a surfactant, sodium hydroxide or sodium hydroxide with methanol, heated to 180 ^o C, and upon reaching the optimum permeability in the array, which occurs when the compression deformations change in tensile strain. To bring the formation into an oscillatory state, the vibration is produced in stages:
first, oscillations in the formation are excited in the formation in a wide frequency range from 60 to 1500 Hz, using parts of the casing with a rare-earth element deposited on them as vibration sources when a pulsed exciting voltage is applied to it;
then they switch to frequencies of 1–20 kHz, exciting them in the formation with a pump laser, and initiate cavitational phenomena in the formation together with injection of softening solutions into the formation with the addition of proppants in the amount of 1.2–1.8% with sizes 0, 03-0.6 mm and a density of 3.2-6.3 g / cm ³ , and proppants, getting into the pores and fractures of the reservoir, do not allow to close and serve, in addition, as concentrators of new cracks in the path of propagation of powerful vibrational vibrations , which, in turn, increases the permeability of rocks and makes pores and cracks intermittent, which increases oil recovery from 10 to 40% compared to the original. To control the state and properties of the formation, cavitational explosions are initiated along the propagation path of powerful vibrational vibrations, that is, tiny bubbles filled with steam or gas or a mixture of them burst in the zone of rarefaction of the elastic wave, collapse in the zone of compression of the elastic wave, resulting in a sharp increase in the permeability of the formation .

To increase the flow rate of oil or gas, along with vibration effects, the following additives are added to the working fluid injected into the reservoir, depending on the properties of the produced oil:
strong alkalis;
water at an ambient temperature containing water-soluble carbonates and phosphates;
liquid fluids with the temperature of their geological environment and additives of alkaline agents, such as alkali metals, and soluble agents, quinoline and others, to emulsify a viscous oil;
with viscous oil, including bitumen, hot aqueous solutions with a content of 0.6% caustic soda are injected into the reservoir;
steam is injected containing alkali metal carbonates and insulating agents such as sulfates, alkali metals, sulfites, polyphosphates, polyamine, polyacetates and others;
injection of hot water with alkalis;
steam containing enough alkaline agents to raise the pH of the processed fluid to 7.5 and alkaline agents ammonia or alkali metal compounds;
dilute aqueous solution of alkalis and steam together.

 Thus, resuscitation of a dry well using vibration in a wide frequency range, together with injection into the formation and displacing rocks of softening materials, reduces the tensile strength of the rocks from 20 to 60%, after which pulsed hydraulic fracturing to connect the well to the formation allows oriented cracks in the direction the action of the minimum principal stress in the formation, into which proppants are injected along with the working fluid, which do not allow hydraulic fractures to close and with puddles with new crack concentrators.

 To protect the surrounding geological environment and reduce the negative dynamic manifestations of soil subsidence, man-made earthquakes, fastening solutions are injected into the worked out parts of the formation along with vibration effects, which increase the diffusion capacity of solutions and increase their adhesion strength to the rock massif by 20-40%, which was tested by hydraulic fracturing to and after vibration exposure.

The essence of the method lies in the fact that under the influence of vibrational vibrations on the propagation path of elastic vibrations, compression and tensile waves arise that affect fluid fluids and gas components contained in the pores and fractures of the formation and host rocks as a tectonic pump, and facilitate their migration to tens and hundreds of times faster than in the absence of an elastic wave, as a result of which, on the propagation path of an elastic wave, there are:
a) redistribution of the field of elastic stresses along the path of migrating fluids;
b) partial degassing of the local section of the reservoir and cavitating phenomena that occur on the propagation path of the elastic wave, provided that
the direction of propagation of the elastic wave coincides with the direction of the extension of pores and cracks in the array;
the wavelength is commensurate with the size of these pores and cracks;
the frequency of the probe pulses is close to the frequency of the natural vibrations of the fluids contained in the pores and cracks;
on the propagation path of an elastic wave there are gradients of pressure and temperature;
the presence of solid inclusions in fluid-containing solutions that serve as cavitation nuclei;
differences in pressure gradients along the wave propagation path due to asymmetric arrangement of pores and cracks in space.

 All of these factors significantly increase the hydro- and aerodynamic bonds of the formation rocks and greatly simplify the task of obtaining — the formation of oriented cracks during hydraulic fracturing.

The advantages of the method are:
the ability to work in the selected frequency range with subsequent injection of elastic energy into the formation to control the state and properties of the formation;
increasing the permeability of formation rocks;
increasing the fracturing area and reducing the energy intensity of the process due to operation in the resonant mode;
enhanced oil recovery from 10 to 40% compared to the original.

 Using the claimed invention will significantly reduce the risk when drilling for oil and gas of dry wells and increase their oil recovery compared to existing methods.

 The expected economic effect is 600-900 thousand dollars / year per year.

Claims (6)

 1. A method of resuscitation of dry oil and gas wells, including drilling a well, running a casing into it, placing vibration sources at the depth of the formation, determining the direction of the main stresses in the rock mass, and then creating cracks oriented in the direction of the minimum principal stress by pumping in a pulsating fluid well in combination with vibration, characterized in that before the casing string is run, a layer of substance is applied to it, consisting of a rare-earth element with the addition of 5 10% binder and built-in electrodes, connect the electrodes to a voltage source to generate elastic vibrations, record elastic vibrations with seismic equipment, determine the location of the field, set packers in the interval of exposure with an interval of 2 30 m, perforate the casing between packers and carry out a phased vibration first in the frequency range of the transitional mode, and then with a frequency equal to the frequency of the massif, measure the stress-strain The state of the rocks in the massif is determined and the pressure amplitude in the alternating wave is determined, after which vibroexposure is carried out with a pressure amplitude equal to 0.5 of the value of the breaking stresses during the time at which the compression deformations transform into tensile deformation, then they act at a frequency equal to the injection frequency working fluid into the well until fracturing is achieved, while a heated solution of sodium hydroxide or sodium hydroxide with methanol and 3 5% surfactant is used as the working fluid m surfactants substance. 2. The method according to claim 1, characterized in that the vibration during the transition mode is carried out in the frequency range 600 1500 kHz, and as the working fluid use a solution heated to 180 ^o C. 3. The method according to claim 1, characterized in that the vibration in the transition mode is carried out in the range of 1 to 2 kHz with a laser beam supplied from the surface of the well through the fiber, and as a working fluid, a solution is used, heated to 60 80 ^o C, and cavitational phenomena initiate in the rock mass.  4. The method according to claim 1, characterized in that before carrying out the hydraulic fracturing, cement slurry is supplied to the base of the well, and vibration exposure is carried out sectionwise during the process of pumping cement into the annular space and with the beginning of the process at the base of the well, vibration exposure being carried out over time, at where the strength of the cement stone reaches half the strength of their standard value. 5. The method according to p. 1, characterized in that 0.6% of caustic soda and 1.2 1.8% of proppants with a particle size of 0.03 0.6 mm and a density of 3.2 6.3 are added to the working fluid g / cm ³ .  6. The method according to claim 1, characterized in that after fracking in the resulting cracks and voids of anthropogenic nature, injection fastening solutions are injected.