RU2478438C2 - Method of combined device to generate pressure oscillation in fluid flow - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to oil production and may be used for increasing reservoir recovery. Method of generating pressure oscillations of fluid flow injected into oil reservoir consists in creating circular jet Helmholtz jet generator to be fed to sharp edges of outlet annular channel and generating pressure oscillations of edge tone frequency. Note here that resonator chamber of said Helmholtz generator increases pressure oscillation amplitude while sleeve arranged coaxially inside outlet channel to make a Galton whistle cavity resonator amplifies pressure oscillations generated by said outlet channel inner edge. Proposed device differs from know designs in that single device with common feed nozzle and outlet annular channel combines two resonators tuned in-phase.

EFFECT: generation of oscillations in several frequencies.

4 cl, 1 dwg

Description

The invention relates to the oil industry, and can also be used in the chemical industry in the preparation of emulsions.

A known method of generating pressure fluctuations in the fluid flow, implemented in the device (see application No. 481327 of 08/25/1975), which consists in the fact that they install a coaxially annular feed nozzle and a cylindrical body with an end in the chamber with the output channel, an annular jet is fed liquids from the nozzle to the sharp lateral edges of the cylindrical body, excite pressure fluctuations with the frequency of the edge tone and form a wave field around the cylindrical body.

This method of generating pressure fluctuations in the fluid flow is based on deformation of the jet upon its collision with a solid obstacle and the destruction of its internal structure. When a jet flows on the end face of a cylindrical obstacle along the side walls of a cylindrical body, a pronounced stagnant region forms with an annular reverse vortex and a whistle-like flow is formed in which the main high-speed jet is in contact with the surface of the stagnant region and intense shear stresses arise at the interface, causing pressure pulsations .

The disadvantage of this method of generating pressure fluctuations is the small amplitude of the oscillations due to the low efficiency of converting the kinetic energy of the jet into the energy of the oscillatory motion of the medium.

A known method of generating pressure fluctuations in the fluid flow, the closest in technical essence and adopted as a prototype, implemented in the device (see application No. 284466 from 01/01/1970), which consists in the following: set coaxially inlet ring nozzle and resonator sleeve with the bottom into the chamber with the outlet channel, an annular stream of liquid from the nozzle is fed to the sharp lateral edges of the resonator sleeve, excite pressure fluctuations with the frequency of the edge tone, amplify the oscillations in the resonating liquid column inside the sleeve and form a wave ovoe field around the sleeve.

This method is based on two main mechanisms - the generation of pressure fluctuations in the flow when it flows onto the sharp edge of the side wall of the sleeve (edge tone) and a significant amplification of the resulting vibrations using a resonator - a liquid column enclosed in the sleeve (using resonance). In this case, a prerequisite for the response, or amplification of oscillations by the system, is the coordination of the operating parameters of the jet flowing to the edge and the ratio of the geometric dimensions of the sleeve itself. To achieve resonance of the oscillatory system, it is necessary to match the frequency of the edge tone and the natural frequency of the resonator — the column of liquid filling the sleeve.

An annular nozzle and a sleeve with a bottom are installed coaxially with a certain interval in a chamber having an output channel. The liquid is supplied with excess pressure into the nozzle and an annular jet is formed at the outlet of the nozzle, which is directed to the sharp annular edge of the side wall of the sleeve. When a jet flows on a sharp edge, harmonic pressure fluctuations are generated, characterized by the frequency of the edge tone, which propagate in the sleeve, form an incident wave and, reflected from its bottom, form a reflected wave. When the phase of the incident and reflected waves is matched, a standing wave is established in the liquid column, and the amplitude of the oscillations emitted by the resonator increases many times.

The disadvantage of this method of generating pressure fluctuations is the monotony of the frequency of the generated oscillations.

The Helmholtz inkjet resonator is known which is closest in technical essence and is taken as a prototype (see Experimental Study of a Jet-Driven Helmholtz Oscillator, J. Fluids Eng., September 1979, Volume 101, Issue 3, p. 383, doi: 10.1115 / 1.3448983), which is a hollow body of revolution, including: a shell secured between two bottoms; inlet nozzle installed in one bottom; and an outlet channel coaxial with the nozzle with sharp edges arranged in the opposite bottom.

The Helmholtz jet resonator consists of two flat parallel bottoms, between which a shell is clamped. Usually the shell is cylindrical, but there are square shells. At the same time, a round inlet nozzle is arranged in one flat bottom, which can protrude into the chamber, and a round outlet channel with sharp edges is organized in the opposite flat bottom. The output channel is a sharp-edged bush mounted in the bottom of the generator. The sleeve may also protrude into the chamber. The nozzle and the outlet channel are coaxial with respect to each other and are located on the axis of the cylindrical shell.

The disadvantage of the generator, taken as a prototype, is the round filled shape of the output channel, which does not allow to generate pressure fluctuations at several frequencies.

The technical result is achieved due to the fact that in the method of generating acoustic vibrations in a fluid stream, which consists in installing a coaxially annular feed nozzle and a resonator sleeve with a bottom in a chamber with an output channel, an annular liquid stream from the nozzle is supplied to the sharp lateral edges of the sleeve -resonator, excite pressure fluctuations with the frequency of the edge tone, amplify the oscillations in the resonant column of liquid inside the sleeve and form a wave field around the sleeve, in the chamber the output channel organizes an annular cross-section in which the resonator sleeve forms the inner wall, and the outer cylindrical wall of the channel is also made with a sharp inlet edge and the annular liquid stream is supplied to the outlet channel so that the annular liquid stream touches both the external and internal sharp edges when flowing into the channel the output channel, while generating on the outer edge of the output channel additional vibrations with their frequency of the edge tone and increase their amplitude in the resonating chamber volume.

In the Helmholtz jet resonator, which is a body of revolution and includes: a shell secured between two bottoms; inlet nozzle installed in one bottom; and the output channel with sharp edges coaxial with it, organized on the opposite bottom, a Galton whistle is placed in the device as follows: - the input nozzle is circular and the output channel is also circular due to the installation of a resonator sleeve with sharp edges and bottom in the center of the channel.

The proposed method for generating pressure fluctuations is as follows.

The operation of the Helmholtz jet resonator includes two main mechanisms - the generation of pressure fluctuations in the flow when the jet flows onto the sharp edge of the output channel (edge tone) and the amplification of the oscillation amplitude by the resonator - a liquid column enclosed in the chamber volume (resonance).

When a flooded jet moves in the chamber of a Helmholtz resonator, it carries away the surrounding layers of a stationary fluid with its motion, which leads to the formation of uniformly alternating circular vortex formations on the surface of the jet. These vortex formations are carried away by the jet and hit the sharp edge of the outlet channel, which causes local pressure disturbances near the edge and pressure fluctuations in the surrounding space. If the frequency of pressure surges at the edge coincides with the frequency of natural oscillations of the liquid column filling the resonator chamber, then their amplitude increases significantly. In this case, the camera acts as a volume resonator - an amplifier of acoustic vibrations, and the natural frequency of the resonator is a determining factor in the formation of the frequency of pressure fluctuations in the fluid flow. Thus, the frequency of pressure fluctuations in the fluid flow will correspond to the natural frequency of the oscillations of the jet resonator chamber.

The Galton whistle is an oscillatory system, including an annular nozzle and a bushing with a bottom, mounted coaxially and with a certain interval (see L. Bergman. Ultrasound and its use in technology, p.27, ill, M., 1957).

The same mechanisms determine the operation of the Galton whistle — the generation of pressure fluctuations when the jet flows onto the sharp edge of the sleeve and the increase in the amplitude of the oscillations by a volume resonator — a column of liquid filling the sleeve. In this case, the frequency of pressure fluctuations in the flow is determined by the natural frequency of the resonator, regardless of the frequency of the ring vortices surrounding the liquid stream.

Each device, both the Helmholtz jet resonator and the Galton whistle, generates oscillations of a certain frequency, the jet resonator generates oscillations with a frequency corresponding to the natural frequency of the liquid column enclosed in the chamber volume, and the Galton whistle with a frequency corresponding to the natural frequency of its volume resonator - bushings with bottom.

The proposed device allows you to combine both oscillatory systems in a single design, and one feeding ring nozzle works on both systems immediately due to the fact that the ring stream of liquid flowing from the nozzle, with its outer part, causes the sound of the Helmholtz resonator chamber, and the inside of the whistle chamber Galton.

The round jet has more stability and range, but in the acoustic sense, these are useless advantages, because in the chamber of the Helmholtz resonator the oscillating element is the shell of the jet flowing onto the sharp edge of the output channel. In the Galton whistle, on the contrary, the generating element is the inner surface of the jet when the jet flows onto the edge of the sleeve.

In the combined device, the in-phase of both resonators should be ensured. To do this, ensure the mobility of one of the walls of the Helmholtz resonator and the bottom of the resonator sleeve. This will ensure tuning and matching of the natural frequency of the Helmholtz resonator chamber and the natural frequency of the Galton whistle-resonator sleeve.

The proposed method allows using two devices to form two independent in-phase wave fields in a fluid flow.

Figure 1 presents a diagram of a device in which a Helmholtz jet resonator and a Galton whistle are combined.

The combined generator of pressure oscillations consists of two independent resonators having a common feeding ring nozzle 1. The Helmholtz resonator consists of a housing 2 sandwiched between two flat covers 3 and 4, and a sleeve 6 with sharp edges and a bottom is installed in its output channel 5, which is a resonator Galton's whistle.

The device operates as follows. At the exit of the annular nozzle 1, an annular jet is formed, which is directed into the annular outlet 5. The jet strikes its outer part into the sharp outer edge of the outlet channel 5, causing the sound of the Helmholtz resonator, and its inner part into the sharp edge of the sleeve 6, making the resonator sound Galton's whistle. Each resonator sounds at its own frequency, and the device simultaneously sounds at two main frequencies.

It is possible to carry out a resonator sleeve with a hole in the bottom, since when operating in resonance mode, the bottom of the sleeve is substantially heated and a small flow of liquid will allow cooling this structural element.

It is possible to make the feeding nozzle a round, filled profile. Then the Galton whistle turns into a Hartmann resonator, differing only in the shape of the feeding nozzle. The mechanisms for generating pressure oscillations with a sharp edge and an increase in the amplitude of oscillations by the resonating liquid column are the same as in the Galton whistle. In this case, it is only necessary to provide that the jet falls both on the edge of the resonator sleeve and on the outer edge of the annular channel, causing the sound of the resonating chamber in the Helmholtz jet resonator.

In the most general case, both resonators can each sound at their own frequency, determined by the frequency of the natural oscillations of these cameras. But more interesting is the operating mode of the device as a whole, when the eigenfrequencies of both resonators are selected so that the phases of the emitted wave fields coincide. The interference of waves coinciding in frequency and phase will lead to a significant increase in the amplitude of the oscillations. To do this, you can make a Helmholtz resonator with a movable bottom like a piston on a rod, or move the entire sleeve axially inside the chamber, and perform a cavity chamber at the Hartmann generator or Galton whistle with a movable bottom.

Claims (4)

1. A method of generating acoustic vibrations in a fluid stream, which consists in installing a coaxially annular feed nozzle and a resonator sleeve with a bottom in a chamber with an output channel, supplying an annular jet of liquid from the nozzle to the sharp lateral edges of the resonator sleeve, inducing pressure fluctuations with the frequency of the edge tone, amplify the oscillations in the resonant column of liquid inside the sleeve and form a wave field around the sleeve, characterized in that the output channel in the chamber is organized into an annular section in which the sleeve is cut the ator forms an inner wall, and the outer cylindrical wall of the channel is also made with a sharp inlet edge and an annular liquid stream is supplied to the outlet channel so that the annular liquid stream touches both the external and internal sharp edges of the annular channel when they flow into the channel, on the outer edge of the output channel, additional vibrations with their frequency of the edge tone increase their amplitude in the resonating chamber volume. 2. The combined hydrodynamic generator of acoustic vibrations, consisting of a Helmholtz jet resonator, which is a body of revolution and includes: a shell secured between two bottoms; inlet nozzle installed in one bottom; and an output channel with sharp edges coaxial with it, organized in the opposite bottom, characterized in that the Galton whistle is arranged in the device as follows: the input nozzle is circular and the output channel is also circular due to the installation of a resonator sleeve with sharp edges in the center of the channel and bottom. 3. The combined hydrodynamic generator of acoustic vibrations according to claim 2, characterized in that a through hole is made in the bottom of the resonator sleeve. 4. The combined hydrodynamic generator of acoustic vibrations according to claim 2, characterized in that the sounds of the Helmholtz jet resonator and the Galton whistle are in-phase tuned.