RU2555738C2 - Method and device for excitement of wave field on injection well face - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: group of inventions relates to oil producing industry and intended for improvement of oil recovery of productive formations. The method of excitement of wave field on the injection well face consists in that the flat constrained flow of liquid is supplied continuously from the slot-hole nozzle to the wedge nose. Meanwhile the area of primary generation of vortex structures in the zone behind the nozzle cut edge is formed. Periodic breakdown of ring vortex structures from the nozzle cut edge, their movement with flow and impact with the wedge nose are provided. Pressure disturbances are generated at deformation and destruction of vortex structures on the wedge nose. Propagation of periodic pressure disturbances from the wedge nose extensively in the form of elastic waves and their chaotic reflection from surrounding walls is performed. The excitation by energy of multiple vortex structures due to energy of elastic oscillations achieving primary generation area is conducted. The liquid flow on the wedge nose is deflected to one of two diverging outlet channels. The flow is divided at the inlet upstream the output channel and sent partially to the lateral chamber interfaced with the nozzle edge and the output channel. In the chamber the pressure is increased due to piston effect of the supplied flow and the flow is pushed away to the opposite output channel, formed from two of its sides by the pressure difference. Periodic switching of the liquid flow direction between output channels is provided. The liquid is displaced alternately from the diverging channels into the common punched output collector. The field of elastic oscillations is excite on the injection well face. Thus the elastic waves reflected from walls of each chamber are focused on the nozzle cut edge interfaced to it.

EFFECT: improvement of efficiency of conversion of kinetic energy of the flow to oscillatory energy of the wave field.

2 cl, 1 dwg

Description

The invention relates to the oil industry, and may also be used in the chemical industry for the production of emulsions.

A known method of exciting a wave field at the bottom of an injection well, the closest in technical essence and adopted as a prototype, implemented in the device (see application No. 2008108054/03 of February 29, 2008, published on October 10, 2009, patent No. 2369734), consisting in that: a flat constricted stream of liquid is fed continuously from the slotted nozzle to the nose of the wedge; this forms the region of primary generation of vortex structures in the zone beyond the edge of the nozzle section; provide periodic disruption of the annular vortex structures from the edge of the nozzle section, their movement with the jet and collision with the nose of the wedge; generate pressure disturbances during deformation and destruction of vortex structures on the nose of the wedge; carry out the propagation of periodic perturbations of pressure from the nose of the wedge in all directions in the form of elastic waves and their chaotic reflection from the surrounding walls; create energy pumping of multiple vortex structures due to the energy of elastic vibrations reaching the region of primary generation; deflect a stream of liquid on the nose of the wedge into one of two diverging exhaust channels; separating the jet at the inlet in front of the exhaust channel and directing the jet partially into the side chamber associated with the nozzle edge and the exhaust channel; increase the pressure in the chamber due to the piston effect of the supplied jet and push the jet into the opposite output channel by the pressure drop created on both sides; provide periodic switching of the direction of the liquid jet between the outlet channels; pushing fluid alternately from diverging channels into a common perforated outlet manifold; excite the field of elastic vibrations at the bottom of the injection well.

This method of exciting the wave field at the bottom of the injection well is based on the formation of elastic waves in the resonator chamber of the jet generator when pumping liquid through its channels and applying pressure pulses to the bottom of the well through the perforation holes of the generator output manifold.

Fluctuations in the pressure of the fluid flowing through the jet generator occur upon the collision of vortex structures that periodically break from the nozzle edge with a sharp nose of a wedge mounted in the plane of symmetry of the device and directed towards the flow. Vortex structures break down from the nozzle edge strictly periodically, similar to how drops of water periodically break down from the spout of a water tap in the bathroom. The deformation and destruction of vortex structures on the nose of the wedge is accompanied by perturbations of pressure in the flow, which propagate with the speed of sound in all directions, including directly into the region of primary generation of vortex structures beyond the nozzle exit edge. Through the body of the jet, if the flow rate is less than the speed of sound. These pressure perturbations add their energy to the energy of the detached vortex structures, further enhancing the pressure fluctuations on the nose of the wedge. This interaction is called a feedback mechanism.

Those pressure disturbances formed on the nose of the wedge, which are directed in the form of a wave of elastic vibrations in different directions, randomly reflect from the walls and quickly decay. The feedback mechanism and energy pumping of the primary generation region is important for the operation of the device as a whole.

Pressure fluctuations propagate in the fluid flow to the bottom of the well, forming a wave field of elastic vibrations in the bottomhole zone.

The disadvantage of the method taken as a prototype is the low efficiency of the feedback mechanism, since an insignificant part of the wave energy of pressure disturbances on the wedge nose reaches the primary generation region beyond the nozzle exit edge.

Known jet generator of elastic oscillations in a fluid stream, designed to excite a wave field in the bottomhole zone of injection wells, the closest in essence and taken as a prototype (see application No. 2008108054/03 of 02.29.2008, published on 10.10.2009. (patent No. 2369734), consisting of: a slotted nozzle with exit edges on the cut, forming a flat cramped jet; a wedge with a sharp nose mounted towards a moving fluid; two flat outlet channels, each having its own external input edge and diverging on both sides of the nose of the wedge, which is a common internal input edge of both exhaust channels; two side chambers located on both sides of a flat cramped jet between the nozzle exit and diverging exhaust channels that exit into a common perforated manifold.

The jet generator consists of a slotted nozzle through which fluid is supplied to the device, a symmetrical wedge with a sharp nose, installed at some distance from the nozzle exit towards the liquid stream, two exhaust channels diverging from the wedge nose, two side chambers located on both sides of the flat jet between the nozzle exit and the outlet channels and the perforated manifold into which the outlet channels exit.

The sharp nose of the wedge represents the common input inner edge of the exhaust channels, and the external input edge of each exhaust channel is its own, and at this point (in projection onto the secant longitudinal plane) the external wall of the channel is conjugated with the wall of the side chamber (see Fig. 1). On the other hand, the wall of the side chamber is associated with the corresponding cut edge of the nozzle. The edges of the walls of the side chambers tend to be sharp on both sides, both at the interface with the nozzle cut and at the interface with the outer walls of the exhaust channels. Both exhaust channels exit into a common perforated reservoir, through which the liquid spent in the generator is pumped into the productive oil reservoir.

The walls of the side chambers have an arbitrary profile selected for reasons of convenience of manufacturing parts.

The disadvantage of the generator, taken as a prototype, is the design of the walls of the side chambers, which does not allow directing all the energy of the incident waves to the edge of the nozzle exit into the region of primary generation of vortex structures.

The technical result is achieved due to the fact that in the method of exciting a wave field at the bottom of an injection well, which consists in that: a flat constricted stream of liquid is fed continuously from the slotted nozzle to the nose of the wedge; this forms the region of primary generation of vortex structures in the zone beyond the edge of the nozzle section; provide periodic disruption of the annular vortex structures from the edge of the nozzle section, their movement with the jet and collision with the nose of the wedge; generate pressure disturbances during deformation and destruction of vortex structures on the nose of the wedge; carry out the propagation of periodic perturbations of pressure from the nose of the wedge in all directions in the form of elastic waves and their chaotic reflection from the surrounding walls; create energy pumping of multiple vortex structures due to the energy of elastic vibrations reaching the region of primary generation; deflect a stream of liquid on the nose of the wedge into one of two diverging exhaust channels; separating the jet at the inlet in front of the exhaust channel and directing the jet partially into the side chamber associated with the nozzle edge and the exhaust channel; increase the pressure in the chamber due to the piston effect of the supplied jet and push the jet into the opposite output channel by the pressure drop created on both sides; provide periodic switching of the direction of the liquid jet between the outlet channels; pushing fluid alternately from diverging channels into a common perforated outlet manifold; excite the field of elastic vibrations at the bottom of the injection well; the elastic waves reflected from the walls of each chamber are focused on the adjacent edge of the nozzle cut.

In a jet generator designed to excite a wave field at the bottom of an injection well, consisting of: a slotted nozzle with outlet edges on a section that forms a flat constricted stream; a wedge with a sharp nose mounted towards a moving fluid; two flat outlet channels, each having its own external input edge and diverging on both sides of the nose of the wedge, which is a common internal input edge of both exhaust channels; two side chambers located on both sides of a flat cramped jet between the nozzle exit and diverging exhaust channels that exit into a common exhaust manifold; each side chamber in longitudinal section has the shape of an ellipse, with the outlet edge of the slit nozzle exit being located at one focus of the ellipse, and the wedge nose located at the other focus.

In addition, the wedge nose can be located in one focus of the ellipse, and the other focus can be located in the middle between the outlet edges of the nozzle.

Or, in one focus of the ellipse, the outlet edge of the nozzle may be located, and in the other focus, the inlet outer edge of the outlet channel may be located.

The proposed method of exciting a wave field at the bottom of an injection well is as follows.

In the primary generation region, vortex structures are formed with a supply of energy, which will subsequently be converted into wave energy. Vortex structures are carried away by a stream of liquid and fly into a sharp wedge. Upon deformation and destruction of these structures, their energy is converted into vibrational energy of the wave field. In order to increase the amplitude of the waves propagating in the flow, it is necessary to provide energy to pump vortex structures formed in the primary generation region. Some part of the energy of the vortex structures, which is converted into the energy of elastic vibrations on the wedge, reaches the primary generation region in the form of wave energy, propagating through the body of the jet towards the flow. This is called a feedback mechanism, and it is this mechanism that provides additional energy to pump the primary generation region in the prototype. Most of the wave energy is scattered within the channels and does not reach the primary generation region.

It is proposed to direct a significant part of the wave field energy to the primary generation region, with the exception of that part that falls on the flat side walls of the channel. To do this, it is proposed to make the walls of the side chambers in the form of an ellipse (in a longitudinal secant plane), and to position the source of waves and their receiver at the focal points of the ellipse. The source of the waves is the nose of the wedge, and the receiver of the waves is the edge of the nozzle cut, in any case, the areas adjacent to these objects. The elliptical profile has such a property that all rays incident from one focus are reflected from the wall and reach the second focus. The sum of the incident and reflected angles is the same for all the rays. Thus, in the second focus, all wave energy generated on the nose of the wedge will be collected, with the exception of the part that falls on the side flat walls.

When the vortex structure moves from the edge of the nozzle section to the nose of the wedge, a time equal to t ₁ = ℓ / w passes

where t ₁ - the time required by the vortex structure to overcome the distance between the nozzle section and the nose of the wedge together with the flow,

ℓ is the distance between the nozzle cut and the nose of the wedge,

w is the velocity of the fluid in the stream.

During the reverse movement of the pressure perturbation from the wedge nose to the nozzle exit edge, a time equal to t ₂ = ℓ / s - w passes through the feedback mechanism, where

t ₂ - the time required for the pressure disturbance to overcome the distance back between the nose of the wedge and the nozzle cut towards the flow,

C is the speed of sound in the medium.

So, to provide feedback between the nozzle exit edge and the wedge nose, it takes time to move the disturbance back and forth t ₃ = t ₁ + t ₂ .

During this time, several more vortex structures will have time to form and separate from the edge of the nozzle cut. It follows from the foregoing that the feedback mechanism allows the pumping of some multiple vortex structures, for example, every second, or every third. If, however, the time intervals between the formation of vortex structures and the operation of the feedback mechanism do not coincide, then pumping of vortices by energy will not occur. It is necessary to coordinate the distance between the nozzle cut edge and the wedge nose ℓ with the jet velocity w.

It is known that the path length of all rays between the foci in the ellipse is the same. This means that in addition to focusing the wave energy on the nozzle cut region, it is possible to provide the necessary multiple vortex structures due to the profiling of the walls of the side chambers. If the feedback mechanism provides, for example, amplification of every third vortex structure, and the shape of the walls of the side chambers allows you to reinforce every sixth vortex structure, then this every sixth vortex structure will have a particularly significant energy.

The proposed method of exciting a wave field at the bottom of an injection well allows one to obtain a large amplitude of oscillations and more efficiently convert the kinetic energy of the jet into the vibrational energy of the wave field.

Figure 1 presents a diagram of a jet generator with a perforated collector.

The jet generator of elastic vibrations in a fluid stream consists of flat milled parts forming a flat channel sandwiched between two flat walls. The slotted nozzle 1 (see FIG. 1) with a smooth entrance is formed by two parts, the side chambers 2 are formed by several parts, while the surface of the parts facing the flow has an ellipse projection onto the cutting plane. The outer walls of the exhaust channels 3 scatter in different directions from the nose of the wedge 4 at a certain angle, and a perforated steel manifold is provided at the outlet of the exhaust channels, with which the entire tubing system with a jet generator can rest on the bottom of the sump.

Works jet generator of pressure fluctuations in the fluid stream as follows. A flat liquid flow is formed by a slotted nozzle 1 and is supplied in the form of a cramped jet to the sharp nose of the wedge 3. Due to internal instability, the jet first falls into one of the outlet channels 4. When the jet enters the outlet channel, it touches the outer entrance edge of the channel and part of the stream flows into the side chamber. Due to the piston effect, the pressure in the side chamber increases, and the created pressure drop begins to influence the jet, causing the jet to deviate in the direction where the static pressure is less and jumps to another outlet channel, where everything is repeated again. From both channels, the fluid enters the perforated reservoir 5 and is then pumped into the reservoir.

When rinsing the jet around the nozzle nozzle, pressure disturbances are generated in the adjacent space. These pressure disturbances propagate in all directions in the form of acoustic waves. Those waves that fall on two flat walls that limit the channel are quickly scattered in the stream. And those waves that fall on the profiled walls of the side chambers at any angle are reflected from the walls strictly in the direction of the nozzle cut edge conjugated with the chamber wall.

Claims (2)

1. The method of exciting the wave field at the bottom of the injection well, which consists in the fact that: a flat, cramped stream of fluid is fed continuously from the slotted nozzle to the nose of the wedge; this forms the region of primary generation of vortex structures in the zone beyond the edge of the nozzle section; provide periodic disruption of the annular vortex structures from the edge of the nozzle section, their movement with the jet and collision with the nose of the wedge; generate pressure disturbances during deformation and destruction of vortex structures on the nose of the wedge; carry out the propagation of periodic perturbations of pressure from the nose of the wedge in all directions in the form of elastic waves and their chaotic reflection from the surrounding walls; create energy pumping of multiple vortex structures due to the energy of elastic vibrations reaching the region of primary generation; deflect a stream of liquid on the nose of the wedge into one of two diverging exhaust channels; separating the jet at the inlet in front of the exhaust channel and directing the jet partially into the side chamber associated with the nozzle edge and the exhaust channel; increase the pressure in the chamber due to the piston effect of the supplied jet and push the jet into the opposite output channel by the pressure drop created on both sides; provide periodic switching of the direction of the liquid jet between the outlet channels; pushing fluid alternately from diverging channels into a common perforated outlet manifold; excite the field of elastic vibrations at the bottom of the injection well; characterized in that the elastic waves, reflected from the walls of each chamber, are focused on the edge of the nozzle cut associated with it. 2. A device for exciting a wave field at the bottom of an injection well, consisting of: a slotted nozzle with exit edges on a section forming a flat cramped jet; a wedge with a sharp nose mounted towards a moving fluid; two flat outlet channels, each having its own external input edge and diverging on both sides of the nose of the wedge, which is a common internal input edge of both exhaust channels; two side chambers located on both sides of a flat cramped jet between the nozzle exit and the outlet channels facing a common perforated manifold; characterized in that each side chamber in longitudinal section has the shape of an ellipse, moreover, at one focus of the ellipse is the exit edge of the slit nozzle cut, and in the other focus is the nose of the wedge.