RU2282027C1 - Combined well stimulation method - Google Patents

Abstract

FIELD: oil industry, particularly methods for stimulating production by forming crevices or fractures using explosives.

SUBSTANCE: method involves thermogaschemical and pressure reservoir treatment by means of gas generator. Gas generator comprises cylindrical uncased charge with central round channel and is made of solid-fuel material and is connected to logging cable. The above action is applied by combusting solid-fuel cylindrical charge in productive reservoir interval along with gunpowder gas pressure accumulation in central charge channel. Then combustion energy is transferred to productive reservoir. To remove residual charge components additional charge is used at the end of main charge burning. The additional charge is provided with segments projecting from opposite cylindrical surface sides and parallel to central channel axis. Longitudinal grooves are created in the segments. Distance between the grooves is equal to outer cylindrical charge part diameter. Rate between charge perimeter and each projecting segment base is (6÷9):1.

EFFECT: increased efficiency of well stimulation due to applying combined thermogaschemical, vibro-wave and pressure bottomhole area action with the use of gunpowder charge free of residual dying fuel charge components.

Description

The invention relates to the oil and gas industry, in particular to methods for influencing the borehole zone of the oil and gas reservoir (EOR) in order to increase the influx of oil and gas. Of particular interest is the method for increasing oil production from contaminated during operation, low production and complicated wells, as well as for reanimating old wells, including in fields with high-viscosity oil fractions.

The method is implemented by gas generators - devices based on solid fuel cells (charges) with special equipment, with which they are connected to the geophysical cable and ignited from it by electric current after lowering into the processing interval of the reservoir. As a result of subsequent combustion of charges, thermogasochemical and pressure effects on rocks occur. Thermogasochemical effect leads to the appearance of longitudinal and transverse cracks, the expansion of existing channels and other changes in rocks, as well as favorable in terms of increasing oil and gas production changes in the properties of liquid ingredients in EOR. With significant baric effects, these processes are amplified. In extreme cases (when the pressure from burning the charges is 1.5 ... 3 times higher than the rock pressure), a “hot” hydraulic fracturing of the earthquake zone arises and extended trunk channels additionally appear.

Known analogues of the method for the use of gas generators in conjunction with other technologies. A method for processing an EOR of a well is based on burning a powder charge at the bottom and feeding an acid solution [1]. The known method combines thermal, mechanical and chemical effects. The effectiveness of the method is small, since the chemical effect is produced after shock and heat, that is, the types of effects are separated in time.

A method of processing PPNP [2] includes burning on the face of a powder pressure generator after feeding an acid solution. As a result of its burning, the acid is forced through into the PPZ, after which a slow-acting acid solution is additionally fed to the bottom of the perforation interval and crushed into the formation. The disadvantages of this method are the same. In addition, the protective coating, the connecting nodes of the charges and the accessories of gas generators with charges of the grades PGD-BK-100 and PGD-BK-150 after treatment of the wells remain in it. In some cases, additional well cleaning is necessary for re-opening the formation. There are also known methods of using gas generators in conjunction with liquid fuel-oxidizing compositions, for example [3, 4]. The disadvantage of gas generators, mainly, is that they serve as initiators for igniting these compounds and play a secondary role.

There is also known a method of using a gas generator with a cumulative perforator [5]. The implementation of this method is quite complicated. The main cumulative effect on the production casing and the PPZP occurs due to the perforator. The gas generator only additionally enhances the influx of oil and gas.

A well-known method of fracturing using solid fuel [6]. The method under consideration includes placing a gas generator in the form of a set of cylindrical charges made of a mixed non-detonating solid fuel based on ammonium perchlorate and an organic binder, hermetically sealed in flexible pipes, in the PNA interval and burning it. Ignition of charges comes from a hydrodetonator, located in the fuse of the first charge, installed at the beginning of the horizontal section of the well and triggered by the pressure of the fluid pumped by the pump from the surface. Subsequent transfer of combustion to other charges occurs through an igniter flame-conducting element. In the described method, the ignition assembly is not sufficiently reliable. The mandatory presence of an airtight shell of charges complicates the use of a gas generator under stressful conditions (under loads, high pressures and temperatures).

In addition, a significant drawback of all of the above methods using gas generators is that the thermal, mechanical and chemical effects on PZNP arising from the combustion of charges, is not supplemented by a microwave exposure.

Vibration effects for some types of gas generators exist in conjunction with thermogasochemical and pressure effects. It occurs during vibrational combustion of a solid fuel cylindrical channel charge. With such combustion, high-frequency pressure waves are generated in the charge channel, penetrating the rocks and effecting the pulsed flow of charge combustion products into the reservoir. Additional microcracks and channels are formed in the rocks, pores expand, there is a decrease in the degree of heterogeneity of the PNP, a decrease in the viscosity of oil and other processes. The ultraviolet effect ultimately reduces the maximum pressure at which a "hot" hydraulic fracturing occurs, caused by other related types of impacts on the EOR, and generally enhances the efficiency of the well treatment.

Closest to the invention in technical essence and the achieved effect is the technology of cleaning the well with a gas generator [7]. The considered method includes thermogasochemical and vibration microwave effects on the formation by burning the interval of the productive formation of a powder charge from a solid fuel material with a filler-stabilizer of combustion with a central circular channel. The method is carried out with the simultaneous accumulation of pressure of the powder gases in the cavity of the Central channel of the charge with subsequent transfer of the energy of combustion of the charge into the reservoir, and the length and diameter of the charge are connected by a ratio of 20-40: 1 and with the content of the filler-stabilizer of combustion to the total charge mass of not more than 1.5 % or in the cavity of the central channel of the charge, in which the length and diameter are related by a ratio of 40-120: 1 and with the content of the filler stabilizing combustion to the total mass of the charge is not more than 0.6%, and the pressure of the powder gases from the cavity of the central to charge analogs are transmitted to the formation in the form of pressure pulses through radial through channels made in rows at a distance between rows 20-40: 1 of the length of the central channel to its diameter and through the end surfaces of the charge.

The method is implemented using a device for thermogasochemical treatment of the reservoir [8]. It is a powder acoustic pressure generator (PGDA), which creates an additional vibratory effect due to the creation of acoustic radiation from the central channel of a cylindrical charge. On opposite outer surfaces of the PGDA charge, parallel to the axis of its central channel, longitudinal grooves are made, recessed into the fuel, through which a rope passes to connect the charge to the geophysical cable. The distance between the grooves is less than the outer diameter of the charge.

After ignition of the charge in the well, combustion begins on all its surfaces: from the central and radial through channels, along the ends, from the outer cylindrical surface, including grooves. The fronts of combustion after combustion of the main part of the fuel vault from the central channel and from the grooves occur earlier than from the channel and from the outer cylindrical surfaces due to the different thickness of the fuel vault. In this case, residual charge fragments not connected to each other are formed, the integrity of the charge is violated, and its channel disappears. This leads to a sharp decrease in the resulting (on all surfaces) combustion area and there is a significant drop in maximum pressure in the well. The effectiveness of the thermogasochemical effect on the reservoir, uniquely associated with this pressure, is reduced. At the same time, the vibrational effect on the PNP decreases, which takes place only in the presence of a cylindrical channel in the charge, i.e. in the absence of fragments.

Thus, the location of the grooves in the body of a cylindrical charge, causing its diversity in combustion of the charge, generally reduces the efficiency of processing of PNP. However, it can be increased if such a constructive refinement of the gas generator is achieved, in which the remaining charge fragments are eliminated and the combustion fronts meet simultaneously from the central channel and from the entire outer surface, including grooves.

The purpose of the invention is to increase the efficiency of stimulation of the well by enhancing the integrated thermogasochemical, baric and vibro-microwave effects on PZNP by using a powder charge without residual dying fuel fragments. The goal is achieved by the fact that in the known method of stimulating oil and gas wells with a gas generator containing a cylindrical shell-free charge of solid propellant material with a central circular channel connected to a geophysical cable, thermo-gas-chemical, pressure and bar wave effects on the reservoir are performed by burning this charge in the reservoir interval with simultaneous accumulation the pressure of the powder gases of the cavity of its Central channel with subsequent transfer of combustion energy to the reservoir. New is the fact that the increase in oil inflows is carried out through the use of a charge with segments protruding on opposite cylindrical charge surfaces parallel to the axis of its central channel with longitudinal grooves made in them, the distance between the grooves being equal to the outer diameter of the cylindrical block, and the ratio of the circumference of the block to the base each of the protruding segments is (6 ÷ 9) ÷ 1.

The method is implemented as follows. As a charge use PGDA. The cylindrical channel charge of this gas generator with radial through channels has segments with cable slots protruding on the outer cylindrical surface. The thickness of the charge arch from the channel to the cylindrical outer surface of the charge and from the charge channel to the groove is the same. The ratio of the circumference of the checker to the base of each of the protruding segments is 8: 1.

PGDA is lowered into the well by means of a device for assembling to the required depth in the interval of the reservoir to be processed. After lowering the charge, it is ignited, followed by comprehensive combustion of the charge. As a result, the pressure of the powder gases penetrates from the cavity of its central channel into the formation through radial through channels and ends of the charge, as well as from other surfaces. As the charge channel rises, the combustion fronts meet from the charge channel and from the entire outer surface, including the surface of the grooves. There are no residual burn-out fragments (unlike the prototype).

The calculations showed that the use of a method for treating a well with a PHGD charge of this form (with respect to the prototype method that uses cylindrical charges with grooves for a rope without protruding segments) allows to increase the overall pressure level in the wells by the combustion of the gas generator charge by approximately 25% and increase the duration of the microwave exposure to the EARP. Increased pressure against the background of a longer vibrational microwave exposure contributes to a deeper penetration of combustion products into the formation, an increase in the warming of the PPZN, as well as a more intense shaking of rocks and exposure to liquid ingredients, favorable for increasing oil inflows.

Thus, the application of the proposed method will allow you to clean the PNP at a greater distance from it and increase the efficiency of the treatments as a whole.

The method can be combined with other well treatment technologies. It can be used in various oil producing regions.

Information sources

1. Smartly B.C. Development and operation of oil fields. - M .: Nedra, 1990, p.208-209.

2. Pat. RF №2091570, MKI 6 E 21 V 43/27, 1996.

3. Pat. RF №2147335, MKI E 21 V 43/117, 1999.

4. Pat. RF №2183741, MKI E 21 V 43/263, 2001.

5. Pat. RF №2119045, MKI 6 E 21 V 43/117, 1998.

6. Pat. USA No. 5295545, MKI 6 E 21 B 43/263, 1994.

7. Pat. RF №2103493, MKI 6 E 21 V 43/25, 43/263, 1996 - "The method of processing the reservoir" - the prototype.

8. Pat. RF №2071556, MKI 6 E 21 V 43/26, 1994.

Claims (1)

A method of stimulating oil and gas wells, including thermogasochemical baric and vibrating effects on the reservoir using a gas generator having a cylindrical open-hole charge with a central circular channel of solid propellant material and connected to the geophysical cable, by burning this charge in the interval of the reservoir while accumulating the pressure of powder gases in cavity of its Central channel with subsequent transfer of combustion energy to the reservoir, characterized in that To get rid of the residual fragments of the charge at the end of its burning, a charge is used with segments protruding on opposite sides of the cylindrical surface parallel to the axis of its central channel with longitudinal grooves made in them, the distance between the grooves being equal to the outer diameter of the cylindrical part of the checker, and the ratio of the circumference of the checker to the base of each of the protruding segments is (6-9) ÷ 1.