RU2199659C1 - Technique intensifying oil output - Google Patents

Abstract

FIELD: oil and gas production. SUBSTANCE: invention is intended to raise oil and gas yield of productive pools of oil and gas wells by their exposure to energy of shock wave excited by electric discharge in fluid of bottom zone. Technical result of invention lies in intensified production of oil with less energy consumption thanks to effective action of electrohydraulic pulse shock wave on productive pool of well, in diminished overall dimensions of pulse source of energy and in reduced production cost. With this in mind electrohydraulic shock wave is generated in fluid in bottom zone of well by pulse discharges with the aid of capacitor discharge unit with spark gap sunk into well through casing string. Shock wave is excited from outside of casing string and for this capacitor discharge unit is brought out of limits of casing string through hole made in it. Shock wave generated in fluid is directed into oil-bearing soil to separate oil from soil. EFFECT: intensified oil output. 1 cl, 3 dwg

Description

 The invention relates to the field of the oil and gas industry and can be used to increase oil and gas recovery of productive formations of oil and gas wells by exposing them to the energy of a shock wave excited by electric discharges in the liquid of the bottomhole zone.

 It is known that after the worked life of oil and gas wells, the volume of production in them falls. Various methods are used to intensify the extraction of oil and gas products from wells in operation. These methods and devices include the use of gunpowder, explosives, pumps, electric motors, vibrators, steam generating units as a power drive (Hydraulic Fracturing, Yu.P. Zheltov, Gostoplivotekhizdat, 1957). Each of these methods has serious drawbacks. The use of powder charges and explosives is associated with the need to comply with increased safety requirements not only during work, but also during their storage and transportation. In addition, when using pore and explosives, wave processes affecting productive formations of deposits are difficult to control and practically exclude the possibility of dosed cyclic excitation of waves with a given frequency and power. This disadvantage is compounded by the fact that the charge of the powder or explosive is placed in the bottom hole casing and, naturally, a significant part of the shock wave energy after the explosion is perceived (shielded) by the perforated casing wall. Consequently, with insufficient explosive device power, the action of the shock wave on the reservoir will be insufficient, and with a large charge power, the casing and cement ring behind the column cannot be destroyed.

 There are also known methods in which the impact on the reservoir is carried out by pumping using pumps with special additives or treated with special methods, as well as steam. Such methods also have serious disadvantages, as they involve the use of complex plants containing powerful high-pressure discharge pumps. The pressure drop created when water or steam is injected into the well sometimes amounts to hundreds of atmospheres. If we take into account that an extensive communication system with numerous connections is used for this purpose, it becomes obvious that it is extremely difficult to ensure uninterrupted operation of such equipment. In addition, it should be noted that the equipment used in this case is a large-sized multi-ton installation, the maintenance of which requires a large number of staff. Naturally, such installations require large expenditures of energy resources, namely fuel, water, electricity ("Plants for the production and injection of steam into the reservoir." Series "Machinery and equipment for the oil and gas industry", VNIIOENG, Moscow, 1973).

 The presence of such serious shortcomings forced specialists to seek new ways to intensify oil and gas production, which would be less labor-intensive, expensive and safer and, at the same time, would be universal and easily manageable.

 In the seventies, a direction appeared combining various methods of electrohydropulse exposure to productive formations of oil and gas fields.

 The invention is known (patent US 4074758 "Method for the production of oil and a device for its implementation"). The essence of the invention is to generate an electro-hydraulic shock wave in the well fluid using a capacitor device with a spark gap introduced into the well through the casing. The generated shock wave through the perforations in the casing is sent from the well into the oil-bearing soil to separate oil from the soil.

 This method has significant advantages over the methods described above, and largely eliminates their disadvantages. So for the implementation of this method requires significantly less cost, as the volume of work performed is reduced, less expensive and complex equipment is used, energy costs are reduced. In addition, the method is universal, safe and easy to control, which allows to achieve greater efficiency of enhanced oil recovery, not only by regulating the power of the electric discharge, but the pulse repetition rate. And, nevertheless, having a number of advantages, this method has serious disadvantages. One of these drawbacks is that, as in the methods using powder and explosives, shielding of the generated shock wave occurs by the walls of the casing, and the propagation of hydraulic flow into the reservoir occurs only through perforations made in the casing. As a result, the bulk of the discharge energy is extinguished inside the pipe, and only part of the energy that does not always achieve the main goal, namely, a significant increase in the oil recovery of the reservoir, reaches the reservoir. The increase in electric discharge energy, as with the use of powder and explosives, is limited due to the possible destruction of the casing.

 There are technical solutions that are aimed at eliminating the drawback described in the analogue.

 The invention is known (Patent RU 20907747 "Method of electrohydropulse exposure in oil and gas wells and a device for its implementation"). The essence of this invention lies in the fact that for electrohydropulse exposure in oil and gas wells carry out periodic excitation of an electric discharge between the electrodes. An electrode is used as one electrode, in which there is an inner surface made in the form of a cone, or the wall of a borehole pipe is used as an electrode. The second electrode is placed in the cone of the first electrode. With this arrangement of electrodes, a narrowly directed action of the shock wave is ensured, which increases the effect of the impact on the reservoir. To increase the effectiveness of the impact, the focal length of the wave reflected from the surface of the cone is selected from the condition that the focal points are located on the surface of the impact. In this case, when the hydrate plug is exposed, the focal length of the shock wave reflected from the surface of the cone is selected from the condition that the focal points are located at a distance from the exposure surface to the side of the plug body that exceeds the focal point distance from the borehole wall. With this method, due to the positioning of the electric-discharge device, it is possible to direct the shock wave through the perforated holes made in the walls of the casing, and thus reduce the screening effect of the pipe. The disadvantages of the method include the following: significantly increases the complexity, since it is necessary to repeatedly position the electric-discharge device relative to each or most of the holes perforated in the casing, which is a complex and time-consuming task. In addition, with this design of the electric-discharge device, upon repeated excitation of the electric discharge, wave processes arise that significantly weaken the effect of the shock wave, and, consequently, the effectiveness of its impact on the reservoir.

 Another invention is known (Patent RU 2128285 "Installation for hydro-pulse impact on productive formations"). The difference between this method and the known electrohydropulse methods of influencing productive formations is that they use a casing, the layout of which includes a polyethylene pipe located in the zone of the productive formation, the cavity of which forms a pulsed chamber. The use of a pulse chamber with walls of a more plastic material (polyethylene pipe) than a casing pipe reduces the unproductive energy consumption extinguished in steel pipes. The analysis of this technical solution shows that it is extremely difficult to install a casing string, the end of which, lowered into the well, is made of plastic polyethylene pipe, due to instability and possible destruction of the latter. In addition, in the presence of a cement ring behind the column, the goal of enhancing the effect of the shock wave on the productive formations in comparison with other analogues cannot be achieved, since the wave propagation conditions will be the same as when using a metal pipe at the end of the column.

 Of all the solutions described, the closest in technical essence and the achieved effect to the claimed invention is a group of inventions related to the direction of electrohydropulse impact on productive formations in oil and gas wells. According to the authors, a US patent invention can be selected as a prototype in which the main essential features that are most consistent with the essential features of the claimed invention are most fully represented.

 Indeed, in the inventive method, as well as in the known one, the essence is to generate an electro-hydraulic shock wave in the well fluid using a capacitor discharge device with a spark gap introduced into the well through the casing. The shock wave generated in the liquid is directed into the oil-bearing soil to separate the oil from the soil. The difference lies in the fact that the shock wave is excited from the outside of the casing, while the electric-discharge device is taken out of the casing through the hole made in it.

 Another difference is that the discharge of the electric discharge device outside the casing is carried out sequentially through special holes that are made in the pipe in an amount of at least two, are evenly distributed around the pipe perimeter, and each time after the output of the electric discharge device outside the casing, cyclic electrical discharges are performed .

 The aim of the invention is to increase the intensification of oil production at lower energy costs due to the effective impact of the electrohydropulse shock wave on the productive formation of the well, reducing the dimensions of the energy source of pulses and reducing the cost of the work.

 From the essence of the invention it is obvious that when performing an electric discharge in the bottomhole zone liquid from the outside of the casing, most of the energy of the propagating shock wave directly affects the reservoir and is only partially perceived (shielded) by the casing when the shock wave propagates in the direction opposite to the outside pipes to which the discharge device is displayed. To eliminate this drawback, it is advisable to make several holes in the casing, two or more, placing them evenly around the perimeter of the casing and sequentially removing the electric discharge device into them and effecting cyclic discharges. With this scheme, the shock wave will effectively act on the producing formation surrounding the well at much lower energy costs compared to when the shock wave is excited inside the casing. In addition, with lower energy consumption, the dimensions of the energy block are reduced, and therefore, the task of lowering it into the well through the passage section of the casing is simplified. There may be several options for implementing this method. One of these options is presented in figures 1, 2, 3.

 In FIG. 1 shows the initial position of one of the variants of the electric discharge head, FIG. 2 - the working position of the electric discharge head and in FIG. 3 is a cross section of the processing zone in the working position of the electric discharge head.

 One of the options for an electric discharge head for implementing the proposed method for processing a bottom-hole zone of a well has the following device. The electric-discharge device is powered by a pulse current generator (GIT) and consists (Fig. 1) of a housing 1, a bracket for a spark gap 2 and a slider 3. In the housing 1 there is a positioning mechanism 4 and a drive for moving the slider (not shown), which using rods 5 is connected to a slider 3 having a wedge groove 6. A flexible coaxial current lead 7 passes through the housing 1, connecting the GIT with a bracket of the spark gap 2, which is located in the wedge groove 6 of the slider 3. The upper part of the bracket of the spark gap 2 is mounted on a flexible coaxial current lead 7, while ensures its electrical contact with the conductive outer sheath 1, forming a spark (Figure 2) the gap 8.

 The treatment of the bottomhole zone of the well is as follows.

 Preliminarily, in the bottomhole zone of the well in the casing 9, holes 10 are made in an amount of at least two, which are evenly distributed along the perimeter of the casing 9. The electric-discharge device is lowered into the well to the bottom-hole zone and, using the positioning mechanism 4, is installed so that the bracket of the spark gap 2 is located against one of the holes 10 in the casing 9. Then the slider 3 with the help of rods 5 is pulled to the housing 1. In this case, the bracket 2 of the arrester slides along the bottom of the guide wedge groove 6, displaces I from the axis of the pipe 9 and through the aperture 10 is displayed outside the casing 9 so that the spark gap 8 is at a predetermined distance D from the outer surface of the casing 9, as shown in Figure 2 occupying its operating position.

 After that, through a flexible coaxial current lead 7 from the GIT, a high voltage pulse is applied to the bracket of the spark gap 2, causing an electrical breakdown of the gap between the central conductor of the current lead 7 and the lower part of the bracket of the spark gap 2. As a result of the breakdown, a current pulse is generated in the spark gap 8, generating a shock wave in the surrounding environment.

 Since the spark gap 8 is removed beyond the casing 9, the intensity of the impact of shock waves on the formation is much higher than during a discharge inside the casing. The supply of high voltage pulses to the bracket of the spark gap 2, causing electric discharges in the spark gap 8, is carried out cyclically.

 After performing the required number of electrical discharges, the supply of high voltage pulses to the bracket of the spark gap 2 is stopped. The electric discharge head is reset. Then, the electric-discharge device using the positioning mechanism 4 is installed so that the bracket of the spark gap 2 is located against the next hole 10 in the casing 9, and the cycle of processing the bottom-hole zone of the well is repeated.

 After processing the well by withdrawing the electric discharge device beyond the casing 9 through all openings 10 made in the casing 9, and performing cyclic electric discharges, the electric discharge device rises from the well.

 The possibility of implementing the method was first confirmed on a test bench on which the bottom hole zone of the wells in the ⌀146 mm casing was simulated, in which perforated ⌀20 mm holes were made.

 Tests have shown that the pressure jump at the shock wave front in the medium surrounding the casing, when discharged outside the casing (i.e., according to the proposed method) is 2.2-2.4 times higher than with the traditional method, i.e. e. when discharged inside the pipe with the same parameters.

 From the description of the nature and parameters of the proposed technical solution, it can be seen that the combination of features characterizing this solution is not found in the identified analogues and prototype.

Claims (2)

 1. A method of intensifying oil production, in which the shock wave is excited in the liquid of the bottomhole zone of the well by pulse discharges of an electric discharge device introduced through the casing into the bottomhole zone, and the generated shock wave is transmitted through the liquid of the bottomhole zone from the well into a productive oil and gas bearing formation, characterized in that the shock wave is excited from the outside of the casing, while the electric discharge device is taken out of the casing through the hole made in the casing.  2. The method according to p. 1, characterized in that the output of the electric discharge device beyond the casing is carried out through holes that are made in the casing in an amount of at least two, placing them evenly around the perimeter of the casing, sequentially output the electric discharge device into these holes and carry out cyclically electrical discharges.

Images