RU2171354C1 - Method of wave stimulation of producing formation and device for method embodiment - Google Patents

Abstract

FIELD: oil and gas producing industry; applicable in reduction of water cutting of well production and increase of oil recovery from formation. SUBSTANCE: method includes installation in well of unit of directed wave stimulation and provision of hydrodynamic impacts onto said unit. Device for method embodiment includes weight for delivering of hydrodynamic impacts, hoisting mechanism connected with weight and unit of directed wave stimulation. Unit is formed by, at least, two cylindrical members with axial and radial channels. One cylindrical member is built in cement plug. The other cylindrical members are located above cement plug for possible alignment of axial channels. Lower end of member built in cement blind from below. EFFECT: reduced water cutting of well products, higher oil recovery from formation. 5 cl, 1 dwg

Description

 The group of inventions relates to the oil and gas industry and can be used to reduce water cut in produced products and increase oil recovery.

 A known method of wave action on the reservoir and a device for its implementation (US Pat. RF N 2001254, IPC E 21 B 43/25, publ. 15.10.93,). The known method includes the generation of harmonic waves on a day surface by oscillating from a power drive with a given frequency of a vibration source, the mass-energy parameters of which are consistent with the physical and mechanical properties of the soil. The known device consists of a centrifugal type vibration source, made in the form of two unbalances rotating in antiphase, and a radiating stamp mounted on the day surface.

 A disadvantage of the known method and device is low efficiency due to large energy losses during the passage of the wave from the surface to the reservoir.

 The closest method of the same purpose to the claimed method in the group of inventions according to the totality of features is the method of impacting the reservoir by creating hydrodynamic shocks in the well using tubing with a cement bridge installed in the production string above the reservoir, while preliminary, the lower part of the production string with a cement bridge is separated from its upper part to form a sump, and the tubing string is lowered into the upper part the quality of the production casing (US Pat. RF N 2151283, IPC E 21 B 43/25, publ. 20.06.2000).

 However, in the proposed method, the force of the wave action is not effective enough, since wave oscillations propagate randomly in all directions.

 In addition, to create a powerful hydraulic shock in the known method, it is necessary to create high pressure in the tubing, and with a sharp release of pressure, the entire tubing string performs strong oscillatory movements along the longitudinal axis of the well, which can lead to pipe breakage.

 Also, the creation of powerful hydraulic pulses due to incompressible water can lead to the destruction of cement stone behind the casing.

 Another disadvantage of this method is the inability to control the strength of the wave action.

 The closest device of the same purpose to the claimed device in the group of inventions is a device for effecting a wave action on the reservoir (also from the group of inventions) (A.S. N 1710709, IPC E 21 B 43/25, published 07.02.92) .

 The known device includes a load for striking, made in the form of fluid-filled drill pipes connected by couplings, a lifting mechanism in the form of a winch connected with the load. A block of wave action in the form of an anvil is placed on the bottom of the well at the level of the reservoir. During operation of the device, the load periodically falls on the anvil and creates elastic wave vibrations that are transmitted to the reservoir.

 The main disadvantage of the known device is the impossibility of creating a directed effect of wave fluctuations on other oil-saturated zones that are not covered by water flooding.

 In addition, the device is not efficient enough due to the low power of the elastic wave oscillations created by the impact of the load on the anvil, since when the weight of the load increases, the bottomhole part of the well can be destroyed.

 Another disadvantage is the inability to control the impact force.

 Thus, the problem arose of increasing the effectiveness of the impact on the reservoir by increasing the power of elastic vibrations.

 The technical result achieved in solving this problem is the creation of a directed action of elastic wave vibrations on the residual oil-saturated zones of the reservoir that are not covered by water flooding.

 The specified single technical result in the implementation of the group of inventions according to the object-method is achieved by the fact that in the known method of wave action on the reservoir, including the creation of hydrodynamic shocks in the well with a cement bridge installed in the column, according to the invention, a block of directed wave action is placed in the cement bridge of the column with radial channels, and in the wall of the column corresponding to the radial channels of the aforementioned block, cuts are made, and hydrodynamic shock creates t using the load, eg blanks for a flexible connection, wherein the bottom face is preset oscillation wave absorber.

 It is advisable to perform a wave vibration damper in the form of a rubber gasket.

 Placing a block of directional wave action in a cement bridge makes it possible to carry out directional propagation of elastic wave oscillations over a given height of the well, thereby increasing the power of their impact on the reservoir.

 The creation of mechanical shocks by a blank on a flexible connection allows you to adjust the strength and frequency of elastic wave vibrations.

 The placement of a damper of elastic wave vibrations at the bottom of the well, for example, in the form of a rubber gasket, allows damping elastic vibrations directed to the underlying layers. Also, this gasket protects the cement stone from destruction.

 The specified single technical result in the implementation of the group of inventions for the object device is achieved by the fact that in the known wave action device comprising a load for applying hydrodynamic shock, a lifting mechanism associated with the load, and a wave action unit, according to the invention, the wave action unit is formed at least two cylindrical elements with axial and radial channels, one of which is built into the cement bridge, and the other is placed above it with the possibility of coincidence of their axes x channels, while the lower end of the cylindrical element integrated into the cement bridge is made in the form of a truncated ball, and its axial channel is made blind from the bottom.

 It is advisable to make the radial channels of the cylindrical elements oblique.

 It is desirable that the axial channel of the integrated cylindrical element is at least twice as large as the diameters of the upstream cylindrical elements.

 The implementation of the wave action block in the form of several cylindrical elements with axial and radial channels placed one above the other allows more efficient transmission of elastic wave vibrations along a given length of a well and in a given direction, since the denser the medium, the less the loss of power of elastic vibrations.

 Inclined radial channels are necessary for the directed propagation of elastic vibrations in a given direction, as well as for converting part of the power, mechanical elastic vibrations to hydrodynamic, which increases the effectiveness of the impact.

 The coincidence of the axial channels and a certain ratio of their diameters allows you to convert part of the mechanical elastic vibrations into hydrodynamic.

 The implementation of the lower end of the cylindrical element in the form of a truncated ball and with an axial channel that is deaf from below makes it possible to reduce the destructive force directed towards the bottom and also prevent wave action on the underlying layers.

 The claimed group of inventions meets the requirement of unity of invention, since the group of diverse inventions forms a single inventive concept, moreover, one of the claimed objects of the group — a device for creating directed wave oscillations — is designed to implement another claimed object of the group — a method of wave action on the formation, while both objects are aimed at solving the same problem with obtaining a single technical result.

 A comparison of the method and the device with the corresponding prototypes showed the presence of new actions for the method (installation of a wave impact unit in a cement bridge of a well, creating a hydrodynamic effect using a load on a flexible joint and placing a rubber gasket, slots in the column on the bottom), as well as a new embodiment of the known element and new connections between elements in the device (the implementation of the wave action block in the form of cylindrical elements with axial and radial channels, a feature of their times escheniya, embodiment the lower cylindrical member).

 Thus, we can conclude that each of the objects of the group of inventions meets the criterion of "novelty."

 A search for the distinguishing features of both the method and the device showed the absence of signs that match the above, so we can conclude that each of the objects of the group of inventions meets the criterion of "inventive step".

 The drawing shows the proposed device installed in the well in the context, a General view.

 The device includes a load 1 connected by a flexible connection 2 with a winch 3 at the wellhead. The load is lowered into a well 4, in which a directional wave block formed by a cylindrical element 7 integrated into the cement bridge 8 is placed above the producing formation 5 with an interval of perforation 6. A cylinder 9 is placed above the cylindrical element 7. Both cylindrical elements have axial 10 and radial 11 channels. Slots 12 are made in the column, respectively, to the radial channels of the directional wave block. On the bottom there is a rubber gasket 13.

 The device operates as follows.

 The load 1 on the flexible joint 2 is dumped into the well 4. The load strikes the cylinder 9. In this case, the wave action is transmitted to the cylinder 7 built into the cement bridge and to the reservoir 5 with oil-saturated zones. The rubber gasket 13 dampens the elastic vibrations, preventing them from spreading to the underlying layers and, in addition, prevents the destruction of the face.

 An example of a specific implementation.

 At the Tuymazinsky field, a mesh of wells of the Bobrikov horizon was selected, the distance between them was 400 m. A rubber gasket 150 mm thick was dropped into one of the wells. Then, in the column at a depth of 1100 m from the mouth, 4 ring holes were cut 15 mm high, the distance between the slots was 1.5 m. The slots were made above the perforation interval. Then a cement bridge 90 m high was installed, in which a lower cylinder 40 m long with axial and radial channels was placed. Above the cylinder integrated in the cement bridge, another one was placed, similar to the first, but with an axial channel approximately two times smaller in diameter. A load weighing 10 tons was suspended on a cable. Impacts were carried out with a frequency of 1 hit per minute, while the load was lowered from a height of 10 m from the level of the upper cylinder.

 Impact results were determined from 15 surrounding producing wells. After 15 days of the directed wave action, in three production wells, the water cut of the produced products decreased by an average of 8%.

 Thus, the proposed invention allows to increase the effectiveness of the impact on the reservoir by increasing the power of elastic vibrations by directed wave action and thereby reduce the water content of the produced products and increase oil recovery.

Claims (5)

 1. The method of wave action on the formation, including the creation of hydrodynamic shock in the well with the installation of a cement bridge in the column, characterized in that in the cement bridge of the column there is a block of directional wave action with radial channels, and slots are made in the wall of the column according to the radial channels of the above-mentioned block, and hydrodynamic shocks are created with the help of a load, for example, blanks, on a flexible connection, while a wave vibration damper is installed at the bottom of the bottom.  2. The method according to p. 1, characterized in that they use a wave vibration damper made in the form of a rubber gasket.  3. A device for wave action on the reservoir, including a load for applying hydrodynamic shock, a lifting mechanism associated with the load, and a wave action unit, characterized in that the wave action unit is formed by at least two cylindrical elements with axial and radial channels, moreover, one of them is built into the cement bridge, and the others are placed above it with the possibility of coincidence of their axial channels, while the lower end of the cylindrical element integrated into the cement bridge is made in the form of a truncated joint ra, and its axial channel is made blind from below.  4. The device according to claim 3, characterized in that the radial channels of the cylindrical elements are made inclined.  5. The device according to claim 3, characterized in that the diameter of the axial channel of the cylindrical element embedded in the cement bridge is at least two times the diameter of the axial channel of the upper cylindrical element.