RU2310068C2 - Device for thermogashydraulic reservoir treatment - Google Patents

Abstract

FIELD: oil production, particularly well bore zone treatment to stimulate oil production.

SUBSTANCE: device comprises charge composed of cylindrical sections. Each section is provided with orifices having axes transversal to section joint axis and lie in single plane therewith. The orifices are created in each section along generatrix line extending along charge side. Grooves with sharp edges are created in side surfaces of device head and lower conical cowl. Head walls are provided with openings to communicate head interior with well.

EFFECT: increased efficiency of well bore zone treatment, provision of sparing well treatment regime and increased treatment reliability.

3 cl, 2 dwg

Description

The invention relates to the field of oil production, and in particular to means for influencing the borehole zone of a productive formation, and can be applied to increase the productivity of wells in oil fields.

One of the rational and effective methods of influencing the borehole zone of a productive formation in order to establish reliable hydrodynamic communication between the well and the formation is to break the formation due to pressure caused by the combustion products of the powder charge. Under the influence of liquid and gas pressure equal to or greater than the rock, rocks are irreversibly deformed. The method of fracturing powder gases is based on the mechanical, thermal and chemical effects of gases on rocks and saturating fluids.

Known charge PGD.BK-100M (Rifle-blasting equipment: Handbook / L.Ya. Fridlyander, V.A. Afanasyev, L.S. Vorobyov and others; Edited by L.Ya. Fridlyander, - 2nd ed Rev. and add. - M .: Nedra, 1990, Section 4.1. Powder pressure generators, pp. 109-112). Unpacked sectional powder charge on a geophysical cable, including powder sections made of solid rocket fuel: one ignition section and five main charge sections, installed close to each other. Each charge section has a central channel. In the ignition section of the charge, the diameter of the channel is larger than in the main sections. As the ignition section of the charge, a support tube with pyrotechnic igniters is used. In the upper part, the pipe is sealed with a cable head to which a geophysical cable is attached with two main charge sections with an upper tip attached to it. In the lower part, the pipe is sealed with a plug with a cable attached to it, on which three main charge sections are put on close to the ignition section. At the bottom of the charge there is a tip fixed with a nut. Charge burning occurs from the channel. The lateral surface of the charge has a protective coating that protects the charge from friction and impact on the column. To register the maximum pressure generated in the well by a powder generator, a crasher device is attached to the cable at a distance of 10 m from the upper end of the generator. The value of the created pressure is found according to a special table attached to each batch of crashed columns depending on the degree of compression of the column.

The generator operates as follows.

When an electric impulse is applied through the cable, the igniter is activated, which ignites the starting igniters located in the channel of the support pipe. The resulting combustion products of starting igniters burn through the walls of the pipes and ignite the ignition section of the charge. The products of combustion of the igniter charge ignite the main charges. Charge burning comes from the central channel.

Using these devices does not always give a positive effect. This is due to the fact that the charges are collected on the geophysical cable, at the junction of the charge sections during their burning, overheating and rupture of the wireline cable occurs, the charge sections are disconnected, which can lead to an emergency.

As a prototype, a single-shell sectional charge was selected for gas-hydraulic impact on the formation (RF patent No. 2178072, MKI E21B 43/263, 2000). The device includes an ignition unit and charge sections. They are made of compositions that provide combustion in aqueous, oil-water and acidic environments. The device has one or more ignition sections for igniting the main sections and equipment with parts for collecting charge sections passed through the central channel of each section, and parts for tightening sections close to each other. Equipment is a composite bar, passed through the central channel of each section. Streamlined shape cones are attached to both ends of the section to tighten and tighten the charge sections close to each other. The diameter of the centralizer cones exceeds the diameter of the charge sections. Centering rings are installed between the charge sections. They exceed the diameter of the diameter of the charge sections. Moreover, the rings are made in such a way that the dynamics of charge burning does not change. A diffuser is located between the lower cone-centralizer and the charge sections to divert the gas flow generated during the combustion of the charge. The charge sections do not have a protective coating.

The device operates as follows.

It is lowered into the perforation interval and, on command from the ground panel, it is launched. Combustion occurs over the entire surface of the charge. When the charge is burning, a large amount of hot gases is formed, which through the diffuser fall into the casing. The ignition time of the entire surface of the charge is less than 0.1 s.

The disadvantage of this device is the following. In the prototype, when the charge is triggered, the device acts on the lifting force due to the intense gas intake. As a result of this, the device is thrown up, which contributes to the appearance of cable bends in the zone closest to the device.

This leads to a significant increase in the hydrodynamic resistance of the cable to the upward flows. When the charge is working, hot gases pass the upper cowl and reach the instrument headgear, cable lug, measuring unit and the “logged” cable in the near zone. On the mentioned elements, braking of the ascending flows and the heat concentration of the hot gases occur, which leads to local overheating in the braking zones. In adverse temperature conditions, the cable appears, since its resistance to the upward flow of hot gases increases significantly due to its orientation, which differs from the axial one.

The following factor leads to the accident associated with a breakage in the logging cable in the prototype. When sections of the charge are triggered, the device is thrown up. After that, the device begins to fall down with acceleration and it picks up speed, followed by sharp braking due to cable tension, the potential energy of the device raised by gases is directed to breaking the cable. At the same time, the probability of breaking an overheated cable is high even with minor shock loads.

Well treatment using shellless charges often has to be done in an acid-containing medium, which takes place after acid treatments. In this case, the prerequisites for the destruction of the armor of the cable and the insulation of its cores in the prototype, as well as for cable breakage are amplified.

Thus, in the prototype there are significant prerequisites for increased accident rate associated with failure of the logging cable and its breakage, overheating of the cable lug, instrument headrest, overheating and failure of the measuring unit.

The next disadvantage of the prototype should be attributed to the fact that due to the developed internal surface of the charge, an intense gas intake is caused, leading to the rupture of the cylindrical sections of the charge into many individually dying elements. This mode of charge functioning is uncontrollable, since in this case it is impossible to provide the optimal pressure for fracturing the formation and the law of its change, it is difficult to build the correct technology for processing the formation. The probability of a charge breaking into individual elements is aggravated by the fact that the divider, during the descent into the well through the side openings, can become clogged by viscous elements that impede gas removal from the internal cavity of the charge sections.

Thus, the prototype excludes the possibility of obtaining a given law of a change in pressure in the processing zone.

In addition, the above behavior of the charge in the prototype determines its short-term combustion. This causes a short-term powerful pressure impulse, exerting an increased load on the casing and cement stone, which can lead to an emergency, i.e. to violation of their integrity.

The proposed device allows to reduce the accident rate due to the sparing mode of impact on the formation, as well as to increase the efficiency of processing the borehole zone of the formation and the reliability of the work.

This is achieved by the fact that in the device for thermogas-hydraulic impact on the formation, containing a cable lug with a headpiece connected to the logging cable, an upper and lower cowling body, between which a charge section with a diffuser is located on the rod, discharge openings are made in each charge section along the line generatrix passing along the lateral surface of the charge sections, and on the lateral surfaces of the headgear and the lower cone-fairing made protrusions with a pointed apex, in addition, the walls n golovnika equipped with windows, it informs the internal volume of the reservoir area of the well.

In addition, the axes of the holes in each charge section are perpendicular to the assembly axis of the charge sections and lie on the same plane with it, and the wireline and cable lugs are equipped with a heat-protective coating.

Figure 1 presents the design of the claimed device.

Figure 2 presents the dependence of pressure on time during operation of the proposed device in comparison with the operation of the device according to the prototype.

The device (Figure 1) is lowered into the well in the zone of the upcoming treatment on the logging cable 1, which is rigidly connected through the cable tip 2 to the headgear 3 and the upper cone fairing 4. The charge sections 5, 6 and 7 are placed on the rod 8 and are joined together due to end recesses and protrusions, they are pressed by a spring 9 to the diffuser 10 with holes 11 and to the lower cone fairing 12. The entire assembly is fastened with a latch 13. In the recess of one of the charge sections, an ignition unit 14 with current-carrying wires 15 connected to cable 1 is located. In each with The charge sections along the generatrix of the entire assembly are made with discharge openings 16, the axes of which are perpendicular to the longitudinal axis of the device and lie in the same plane with it. To protect the ends of the upper and lower charge sections, support washers 17 are installed. Safety rubber rings 18 protect the sections from external mechanical stress. The number of charge sections can be different, from 9 pieces or more, depending on the depth of the treated formation. The logging cable 1 and cable lug 2 are equipped with a heat-protective coating 19 up to 1-2 meters long. On the lateral surface of the headgear 3, protrusions 20 with a pointed apex are formed and windows 21 are located that communicate the internal volume A of the headgear with the borehole zone B of the formation.

The device operates as follows.

When current is supplied through the current-carrying wires 15 to the ignition unit 14, ignition of the charge sections occurs. Ignition spreads with high speed along the inner surface of the sections and through the discharge openings 16 is quickly transmitted to their outer surface. Due to the jet of hot gases from the holes 16, the device experiences a force pressing it against the wall of the well, the protrusions 20 on the headgear 3 and the lower cone fairing 12 increase the friction force between the downhole tool and the wall of the well. In this way, the device is prevented from being thrown up, as the energy of the hot gases in this case is aimed at pressing the structural elements of the device to the wall of the well. This circumstance prevents the uphole tool from rising and its subsequent fall. Thus, the probability of tearing the cable 1 away from the tip 2 is reduced. In addition, overpressure is released from the internal cavity of the charge through the discharge openings 16, which prevents a hard operation mode, i.e. with the maximum possible speed, and allows you to get the shape of the pressure curve necessary for effective formation treatment.

The dependence of pressure on time during operation of the prototype and the proposed device is presented in figure 2. Curve 1 is characteristic of the prototype, here the pressure pulse has a high amplitude, but a short duration. A high pressure amplitude has a destructive effect on the casing and cement stone, and the short duration of this pulse does not allow for effective fixing of the cracks obtained in the formation.

Dependence 2 (Figure 2) displays the operation of the proposed device for gas fracturing, which is characterized by the presence of discharge holes 16 (see figure 1) in charge sections. After the formation of cracks in the formation, the pressure from P ₁ in the treatment zone gradually drops to P ₀ , i.e. to hydrostatic, in this case, the obtained cracks are fixed, thus eliminating their quick closure, which is facilitated by pressure and vibration. These vibrations created by the dying charge are caused by changes in pressure on the decline of curve 1 (figure 2). Recession time i.e. crack fixing time is directly proportional to the number of charge sections. For the most effective fixation of the resulting cracks, it makes sense to increase the number of charges, which will simultaneously contribute to a more developed network of cracks.

Curve 2 differs from curve 1 (see figure 2) in that its slopes are more gentle.

Therefore, it is obvious that the treatment of the formation of the proposed device in comparison with the prototype is more sparing in relation to the casing and cement ring.

The headgear 3 has an internal cavity A, which through the windows 21 communicates with the borehole zone B of the reservoir. The headgear 3 partially absorbs thermal energy due to its mass, internal cavity and protrusions 20, which makes it possible to facilitate the temperature regime for cable 1.

In the inner cavity of the headgear 3 can be placed pressure sensors and other control and measuring devices.

Claims (3)

1. A device for thermogas-hydraulic impact on the formation, containing a cable lug connected to the logging cable with a cap, an upper and lower fairing body, between which on the rod there is an assembly of charge sections with a diffuser, characterized in that discharge sections are made along each line in the charge section generatrix passing along the lateral surface of the charge sections, and on the lateral surfaces of the headgear and lower cone-fairing made protrusions with a pointed apex, in addition to the wall ovnika equipped with windows, it informs the internal volume of the reservoir area of the well. 2. The device according to claim 1, characterized in that the axis of the holes in each section of the charge are perpendicular to the axis of the assembly of the sections of the charge and lie with it in the same plane. 3. The device according to claim 1, characterized in that the logging cable and cable lug are equipped with a heat-protective coating.

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